Binding of S-adenosylhomocysteine to various domains of the plasma membrane and to the endoplasmic reticulum from rat liver: Relation between binding and phospholipid methyltransferase activity

S-Adenosylhomocysteine (AdoHcy) binding to various membrane fractions of rat liver was determined at pH 7.4, using an oil centrifugation technique. The highest binding activity was found in the heavy microsomal (M-H) fraction enriched in endoplasmic reticulum, but high binding activity was also observed in the light microsomal fractions enriched in blood sinusoidal membranes (M-L fraction), and the heavy nuclear fraction (N-H fraction) containing the contiguous area. A substantial portion of AdoHcy binding activity in the M-L fraction may be ascribed to contamination of this fraction with endoplasmic reticulum, as indicated by the distribution of NADPH cytochrome c reductase activity. Binding activity was low in the light nuclear (N-L) fraction corresponding to the bile canaliculi. Phospholipid methyltransferase activity was determined in the same membrane fractions under similar conditions (pH 7.4), and in the absence and presence of added phospholipids. The distribution of the enzyme activity was dependent on the presence of exogenous phospholipids, and grossly similar to AdoHcy binding, the highest activities being observed in the M-H and the M-L fractions. The N-H fraction, rich in AdoHcy-binding activity, demonstrated, however, a very low phospholipid methyltransferase activity. It is concluded that AdoHcy-binding activity is not confined to the plasma membranes, and a major fraction of the binding activity resides on membranes derived from the endoplasmic reticulum. Also, the present results add to previous data suggesting that phospholipid methyltransferase does not totally account for the AdoHcy-binding sites on rat liver membranes.     

Biosynthesis of mannoproteins by cell-free extracts fromPhycomyces blakesleeanus

Most of the manosyl transferase activity inPhycomyces blakesleeanus was found associated with a crude membrane fraction sedimenting at 48,400g (R_av). Triton X-100 and Nonidet NP-40 inhibited 95% of the enzyme activity. Digitonin caused 47% of inhibition and when removed, the membrane-bound enzymatic activity increased by about 35%; no activity was detected in supernatant. The rate of mannosyl transfer increased in the presence of 4 or 8 mM Mg²⁺ ions. Several compounds, including glycoproteins, mucoran, and mucoric acid, failed to act as acceptors of mannosyl residues. Guanosine diphosphate and guanosine monophosphate inhibited the transfer of mannosyl residues by 60 and 19%, respectively. Mannosyl transfer involves participation of lipid intermediates.β elimination of the product synthesizedin vitro revealed the presence of mannose, mannobiose, and mannotriose, suggesting that they are bound to protein viaO-glycosidic linkages. The alkaline-resistant carbohydrate part of the glycoproteins consisted mainly of mannose residues that were probably connected to the protein moiety throughN-glycosidic bonds.     

The formation of glycosidic bonds in yeast glycoproteins

Membranes of Saccharomyces cerevisiae were separated on urografin gradients. The specific activity of the light membranes (endoplasmic reticulum), the Golgi-like vesicles and the plasma membrane in transferring mannosyl residues from GDP-mannose to mannoproteins and to dolichyl monophosphate has been determined. The first mannose of the O-glycosidically linked manno-oligosaccharides is incorporated with the highest specific activity by the endoplasmic reticulum. The incorporation of the second to fourth mannosyl groups is catalysed with increasing activity also by the Golgi-like vesicles and the plasma membrane.The incorporation of mannosyl groups into weak alkali-stable positions (N-glycosidically linked chains) is carried out with almost the same specific activity by all three membrane fractions, however, dolicholdependent and-independent steps could not be distinguished as yet.The results are discussed in terms of a sequential addition of sugar residues along the route of export of the mannoproteins. The dolichol-dependent steps seem to occur on the endoplasmic reticulum and thus very carly in the event.Abbreviations GDP-mannose guanosine diphosphate mannose - Dol-P dolichyl monophosphate - Dol-P-mannose dolichyl monophosphate mannose     

Partial purification and characterization of a mannosyl transferase involved in O-linked mannosylation of glycoproteins in Candida albicans

Incubation of a mixed membrane fraction of C. albicans with the nonionic detergents Nonidet P-40 or Lubrol solubilized a fraction that catalyzed the transfer of mannose either from endogenously generated or exogenously added dolichol-P-[14C]Man onto endogenous protein acceptors. The protein mannosyl transferase solubilized with Nonidet P-40 was partially purified by a single step of preparative nondenaturing electrophoresis and some of its properties were investigated. Although transfer activity occurred in the absence of exogenous mannose acceptors and thus depended on acceptor proteins isolated along with the enzyme, addition of the protein fraction obtained after chemical de-mannosylation of glycoproteins synthesized in vitro stimulated mannoprotein labeling in a concentration-dependent manner. Other de-mannosylated glycoproteins, such as yeast invertase or glycoproteins extracted from C. albicans, failed to increase the amount of labeled mannoproteins. Mannosyl transfer activity was not influenced by common metal ions such as Mg(2+), Mn(2+) and Ca(2+), but it was stimulated up to 3-fold by EDTA. Common phosphoglycerides such as phosphatidylglycerol and, to a lower extent, phosphatidylinositol and phosphatidylcholine enhanced transfer activity. Interestingly, coupled transfer activity between dolichol phosphate mannose synthase, i.e., the enzyme responsible for Dol-P-Man synthesis, and protein mannosyl transferase could be reconstituted in vitro from the partially purified transferases, indicating that this process can occur in the absence of cell membranes.     

Involvement of dolichol phosphates as intermediates in the mannosyl and galactosyl transferases of rat testicular germ cell Golgi apparatus membranes

Isolated Golgi apparatus membranes from the germinal elements (spermatocytes and early spermatids) of rat testis were examined for their ability to incorporate [14C]mannose and [14C]galactose into glycolipid and glycoprotein fractions. Transfer of mannose from GDP-[14C]mannose into a Lipid I fractions (GPD:MPP mannosyl transferase activity), identified as mannosyl phosphoryl dolichol, showed optimal activity at 1.5 mM manganese and at pH 7.5. Low concentrations of Triton X-100 (0.1%) stimulated transferase activity in the presence of exogenous dolichol phosphate (Dol-P); however, inhibition occurred at Triton X-100 concentrations greater than 0.1%. Maximal activity of this GDP:MPP mannosyl transferase occurred at 25 microM Dol-P. Activity using endogenous acceptor was 2.34 pmole/min/mg, whereas in the presence of 25 microM Dol-P the specific activity was 284 pmole/min/mg, a stimulation of 125-fold. Incorporation of mannose into a Lipid II (oligosaccharide pyrophosphoryl dolichol) and a glycoprotein fraction was also examined. In the absence of exogenous Dol-P, rapid incorporation into Lipid I occurred with a subsequent rise in Lipid II and glycoprotein fractions suggesting precursor-product relationships. Addition of exogenous Dol-P to galactosyl transferase assays showed only a minor stimulation, less than twofold, in all fractions. Over the concentration range of 9.4 to 62.5 micrograms/ml Dol-P, only 1% of radioactive product accumulated in the combined lipid fractions. These observations suggest that the mannose transfer involves Dol-P intermediates and also that spermatocyte Golgi membranes may be involved in formation of the oligosaccharide core as well as in terminal glycosylations.     

The hydrolysis of the alkenyl group from enthanolamine-plasmalogen by oligodendroglial cell-enriched fractions

The rate of hydrolysis of the 1-0-alkenyl group of sn-1-alk-1′-enyl-2-acyl-glycerylphosphorylethanolamine (alkenyl, acyl-GPE; ethanolamine plasmalogen) by plasmalogenase is higher in oligodendroglial cell-enriched fractions from bovine brain compared with fractions enriched in neuronal perikarya and astroglia. The distribution of plasmalogenase activity in membrane fractions isolated from bovine oligodendroglia has been compared with that of ‘marker’ enzymes. The highest specific activity was in a fraction enriched in plasma membranes, whilst most activity was recovered in an endoplasmic reticulum membrane fraction. In bovine oligodendroglial cell homogenates, the enzyme had a neutral pH optimum, had no requirement for divalent cations and its activity towards 1-alkenyl-GPE (lysoplasmalogen) was half that with alkenyl, acyl-GPE. C₁₆ alkenyl groups were hydrolysed more rapidly than C₁₈ alkenyl groups. With ³H-labelled alkenyl, acyl-GPE as substrate, radioactivity in released aldehydes appeared in fatty acids esterified in phospholipid while the oxidation of fatty aldehydes was blocked by the addition of NADH. An NAD-dependent aldehyde dehydrogenase was found to be present in oligodendroglia which exhibited highest activity towards C₁₄C₁₈ aldehydes (K_m, 2 μM).     

ATP-dependent CA2+ transport in endoplasmic reticulum isolated from roots ofLepidium sativum L.

Endoplasmic reticulum membranes were isolated from roots of garden cress (Lepidium sativum L. cv Krause) using differential and discontinuous sucrose gradient centrifugation. The endoplasmic reticulum fraction was 80% rough endoplasmic reticulum oriented with the cytoplasmic surface directed outward and contaminated with 12% unidentified smooth membranes and 8% mitochondria. Marker enzyme analysis showed that the activity for endoplasmic reticulum was enriched 2.4-fold over total membrane activity while no other organelle activity showed an enrichment. All evidence indicated that the fraction was composed of highly enriched endoplasmic reticulum membranes. Ca²⁺ uptake activity was measured using the filter technique described by Gross and Marmé (1978). The results of these experiments showed an ATP-dependent, oxalate-stimulated Ca²⁺ uptake into vesicles of the endoplasmic reticulum fraction. The majority of the transport activity was microsomal since specific inhibitors of mitochondrial Ca²⁺ transport (ruthenium red, LaCl₃ and oligomycin) inhibited the activity by only 25%. Sodium azide showed no inhibition. The transport was likely directly coupled to ATP hydrolysis since there was no inhibition with carbonylcyanidem-chlorophenylhydrazone. The transport activity was specific for ATP showing only 36% and 29% of the activity with inosine diphosphate and guanosine 5′-triphosphate, respectively. The results indicate a Ca²⁺ transport function located on the endoplasmic reciculum of garden cress roots.     

Mitochondrial biogenesis: do liver mitochondria contain glycoproteins and glycosyltransferases?

1. Subcellular fractions isolated from livers of 19-day-old chicken embryos were analyzed in order to assess whether liver mitochondria contained glycosylated proteins or had mannosyl- or sialyl-transferases that could transfer sugars to mitochondrial macromolecules. 2. Proteins in liver mitochondrial membranes and matrix fractions were screened for their affinities for concanavalin A (Con A). 3. After separation by gel electrophoresis under denaturing conditions, a significant number of the proteins bound [125I]Con A, and the binding of the lectin was substantially inhibited by alpha-methyl-D-mannoside. 4. In addition, radio-iodinated matrix proteins were screened for lectin-binding properties by chromatography on Con A covalently linked to agarose. 5. A number of proteins, representing 14% of those loaded onto the column, became tightly bound to the agarose-linked lectin, and the molecular weights of several of those proteins are reported. 6. Mannosyltransferase activities were measured in fractions highly enriched for mitochondria. 7. In the reactions, mannose was transferred from guanosine diphosphomannose to materials insoluble in 0.3% trichloroacetic acid or in chloroform:methanol (2:1). 8. The fractions also catalyzed the transfer of mannose to materials extractable in chloroform:methanol and which migrated with the Rf of dolichol phosphate on Silica Gel H. 9. Dolichol phosphate stimulated the transfer of mannose to those materials extractable in the organic solvents. 10. Marker enzyme analyses indicated that the mannosyl transferase activity in the mitochondrial fraction could not be accounted for entirely by contaminating microsomal membranes. 11. Although sialyltransferase activity was detected also in the mitochondrial fractions, the levels of the activity and the kinetics of the reactions indicated that Golgi membranes were most likely the sources of the enzyme.     

Formation of α-1,2- and α-1,3-linked mannose disaccharides from dolichyl mannosyl phosphate by rat liver membrane enzymes

Dolichyl mannosyl phosphate and GDPmannose were active substrates for the transfer of mannose to methyl-α-d-mannose, p-nitrophenyl-α-d-mannose, and free mannose with rat liver microsomal membranes. The products formed during dolichyl mannosyl phosphate incubation with methyl-α-d-mannose or with mannose were α-linked. The dissaccharides formed by incubation of dolichyl mannosyl phosphate or GDPmannose with mannose were identified by paper chromatography and electrophoresis as mannose-α-1,2-mannose and mannose-α-1,3-mannose. Synthesis of each product was dependent on the assay conditions used and was most markedly affected by the presence of detergent. Transfer of mannose from either substrate to form mannose-α-1,3-mannose was severely inhibited by Triton X-100.     

Isolation and characterization of plasma and smooth membranes of the marine diatom Nitzschia alba

A procedure is described for isolating plasma, smooth and other cellular membranes from hypotonically lysed protoplasts of the marine diatom, Nitzschia alba. From starting material of approximately 10 g wet weight (10¹⁰ cells), about 168 mg (organic weight) of a membrane-enriched fraction, exclusive of mitochondria, is obtained by differential centrifugation. From this, six membrane fractions are separated on a discontinuous sucrose gradient by isopycnic centrifugation.The plasma membranes, from the density region 1.23-1.29 g/cc, consist of small vesicles and sheets. They are purified approximately 20-fold, based on the increase in specific activity of a (Na⁺-K⁺-Mg²⁺)-ATPase, an enzyme found predominantly in these membranes. They also contain the highest specific and total activity of a (Mg²⁺)-ATPase and, in addition, are distinguished chemically by their high sterol specific content and high molar ratio of sterol/phospholipid (0.792-0.854). The carbohydrate/ protein ratio (0.070-0.072) is appreciably lower than that of the smooth membranes.The smooth membranes separate into two distinct fractions, a light and heavy component, which occur at the top of the sucrose gradient in densities of 1.13 and 1.18 g/cc, respectively. Both fractions are composed of relatively large membrane vesicles and membrane sheets and are distinguished from other membrane fractions by an exceptionally high carbohydrate/protein ratio (0.194-0.294).The light component shows the highest specific content of lipid, phospholipid, neutral lipid, carbohydrate, sialic acid, and RNA, and the highest specific activity of NADPH cytochrome c reductase, 5′-nucleotidase and phosphodiesterase compared to the other five fractions. It shows the lowest Na⁺ plus K⁺ stimulation of the (Mg²⁺)-ATPase. This fraction is probably enriched in endoplasmic reticulum.The heavy component contains some Golgi-like vesicles, sacs and tubules. It is characterized by the highest total content of chemical constituents analyzed, with the exception of RNA, and by the highest specific activity of thiamine pyrophosphatase, uridine diphosphatase, acid and alkaline phosphatase, and glucose-6-phosphatase, suggesting that this component is enriched in Golgi membranes approximately 13-fold.A most striking feature of these diatom membranes is the presence in all fractions of (Mg²⁺)-ATPase activity which is stimulated 5- to 10-fold by the presence of equimolar Na²⁺ plus K⁺. The data clearly differentiate these membrane fractions from each other as well as from membranes prepared from animal cells.     

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.     

Regulation of Plasma Membrane beta-Glucan Synthase from Red Beet Root by Phospholipids : Reactivation of Triton X-100 Extracted Glucan Synthase by Phospholipids

Extraction of red beet root plasma membranes with the detergent Triton X-100 at a level of 2.0% (weight/volume) resulted in the depletion of over 90% of total membrane phospholipid and the reduction of glucan synthase activity by 80 to 90%. Reconstitution of the delipidated Triton X-100, 100,000g fraction in the presence of phospholipids restored glucan synthase activity. The most effective phospholipid was phosphatidyl-ethanolamine, which restored 110 to 144% of the original activity at 0.5% (weight/volume). Glucan synthase in the phospholipid-reactivated Triton X-100-treated fraction was enriched 9-fold in specific activity relative to microsomal membranes but was unstable in digitonin. These results support the hypothesis that glucan synthase activity is regulated by its phospholipid environment.     

Isolation and characterization of a liver plasma membrane fraction enriched in glucagon-sensitive adenylate cyclase

Partially purified liver plasma membranes were fractionated further on sucrose layers. Three membrane populations, numbered Peaks 1, 2 and 3, were isolated at densities of 1.23, 1.16, and 1.03, respectively. Peaks 1 and 2 were enriched to a similar degree in 5′-nucleotidase activity, a plasma membrane marker, relative to membranes in Peak 3. Electron micrographs indicated that Peak 1 possessed desmosomes and bile canaliculi, while Peak 2 contained large vesicles as well as smaller vesicular structures attached to membranes. The latter have been attributed to hepatocyte sinusoidal surfaces. All three membrane fractions contained adenylate cyclase activity with the highest specific activity found in Peak 2. The enzyme in all three peaks was F sensitive with higher sensitivity in Peaks 1 and 2. Glucagon sensitivity of adenylate cyclase in Peak 2 membranes was four times that of Peak 1. Only Peak 2 membranes were sensitive to epinephrine. The Peak 2 membranes were three times more sensitive to glucagon than the partially purified membranes from which they were derived. These findings indicate that, while both bile canalicular and sinusoidal faces of hepatocytes possess adenylate cyclase, the sinusoidal fraction is more sensitive to glucagon. Solubilized adenylate cyclase of the Peak 2 membranes, obtained as the 165,000g supernate of membranes treated with Lubrol-PX, was sensitive to stimulation by guanyl nucleotide analogs. Guanyl nucleotide sensitivity thus resides in the catalytic site and is not dependent on membrane integrity. All three membrane fractions possessed similar activities of nucleotide phosphohydrolase activity.     

Biosynthesis of glycoproteins in Candida albicans: activity of mannosyl and glucosyl transferases

The enzymes dolichol phosphate glucose synthase and dolichol phosphate mannose synthase (DPMS), which catalyze essential steps in glycoprotein biosynthesis, were solubilized and partially characterized in Candida albicans. Sequential incubation of a mixed membrane fraction with increasing concentrations of Nonidet P-40 released a soluble fraction that transferred glucose from UDP-Glc to dolichol phosphate glucose and minor amounts of glucoproteins in the absence of exogenous dolichol phosphate. Studies with the soluble fraction revealed that some properties were different from those previously determined for the membrane-bound enzyme. Accordingly, the soluble enzyme exhibited a twofold higher affinity for UDP-Glc and a sixfold higher affinity over the competitive inhibitor UMP, and the transfer reaction was fourfold more sensitive to inhibition by amphomycin. On the other hand, a previously described protocol for the solubilization of mannosyl transferases that rendered a fraction exhibiting both DPMS and protein mannosyl transferase (PMT) activities operating in a functionally coupled reaction was modified by increasing the concentration of Nonidet P-40. This resulted in a solubilized preparation enriched with DPMS and nearly free of PMT activity which remained membrane bound. DPMS solubilized in this manner exhibited an absolute dependence on exogenous Dol-P. Uncoupling of these enzyme activities was a fundamental prerequisite for future individual analysis of these transferases.     

Effect of diphenyl ether herbicides on oxidation of protoporphyrinogen to protoporphyrin in organellar and plasma membrane enriched fractions of barley

In barley (Hordeum vulgare L.) root cells, activity for oxidizing protoporphyrinogen to protoporphyrin (protoporphyrinogen oxidase), a step in chlorophyll and heme synthesis, was found both in the crude mitochondrial fraction and in a plasma membrane enriched fraction separated by a sucrose gradient technique utilized for preparing plasma membranes. The specific activity (expressed as nanomoles of protoporphyrin formed per hour per milligram protein) in the mitochondrial fraction was 8 and in the plasma membrane enriched fraction was 4 to 6. The plasma membrane enriched fraction exhibited minimal cytochrome oxidase activity and no carotenoid content, indicating little contamination with mitochondrial or plastid membranes. Etioplasts from etiolated barley leaves exhibited a protoporphyrinogen oxidase specific activity of 7 to 12. Protoporphyrinogen oxidase activity in the barley root mitochondrial fraction and etioplast extracts was more than 90% inhibited by assay in the presence of the diphenyl ether herbicide acifluorfen methyl, but the activity in the plasma membrane enriched fraction exhibited much less inhibition by this herbicide (12 to 38% inhibition) under the same assay conditions. Acifluorfen-methyl inhibition of the organellar (mitochondrial or plastid) enzyme was maximal upon preincubation of the enzyme with 4 mm dithiothreitol, although a lesser degree of inhibition was noted if the organellar enzyme was preincubated in the presence of other reductants such as glutathione or ascorbate. Acifluorfen-methyl caused only 20% inhibition if the enzyme was preincubated in buffer without reductants. Incubation of barley etioplast extracts with the earlier tetrapyrrole precursor coproporphyrinogen and acifluorfen-methyl resulted in the accumulation of protoporphyrinogen, which could be converted to protoporphyrin even in the presence of the herbicide by the addition of the plasma membrane enriched fraction from barley roots. These findings have implications for the toxicity of diphenyl ether herbicides, whose light induced tissue damage is apparently caused by accumulation of the photoreactive porphyrin intermediate, protoporphyrin, when the organellar protoporphyrinogen oxidase enzyme is inhibited by herbicides. Our results suggest that the protoporphyrinogen that accumulates as a result of herbicide inhibition of the organellar enzyme can be oxidized to protoporphyrin by a protoporphyrinogen oxidizing activity that is located at sites such as the plasma membrane, which is much less sensitive to inhibition by diphenylether herbicides.     

Relationship between lipogenesis and glycogen synthesis in maternal and foetal tissues during late gestation in the rat. Effect of dexamethasone.

We investigated whether the polyenic and allylic phosphate systems of retinyl phosphate are essential for its mannosyl acceptor and donor activities in rat liver postnuclear membranes. Perhydromonoeneretinyl phosphate, a compound without growth-promoting activity in vitamin A-deficient animals, was prepared by catalytic hydrogenation of retinol and phosphorylation. Perhydromonoeneretinyl phosphate mannose synthesis from GDP-mannose showed continued accumulation for at least 60 min, while retinyl phosphate mannose synthesis showed a maximum at 20-30 min and then declined. Moreover, only retinyl phosphate stimulated transfer of mannose from GDP-mannose to endogenous proteins, which were separated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Thus, hydrogenation of side-chain double bonds in retinyl phosphate impaired only slightly its mannosyl acceptor activity, but caused loss of mannosyl donor activity.     

Dietary effects on the formation of dolichyl monophosphate mannose by microsomal preparations of rat adipose tissue

Microsomal preparations from rat adipose tissue catalyse the transfer of [¹⁴C]mannose from GDP-[¹⁴C]mannose to an endogenous acceptor forming a [¹⁴C]mannosyl lipid. The mannosyl lipid co-chromatographs with hen oviduct dolichyl monophosphate β-mannose on three solvent systems. It is stable to mild alkaline hydrolysis, but strong alkaline treatment yields a compound that co-migrates with mannose 1-phosphate. The mannosyl lipid is labile to mild acid hydrolysis, yielding [¹⁴C]mannose. Formation of the compound is reversible by GDP, but not GMP, and is stimulated by exogenous dolichyl phosphate.

The kinetics of transfer of [¹⁴C]mannose from GDP-[¹⁴C]mannose to form dolichyl monophosphate mannose were studied by using preparations derived from rats fed on one of four diets: G (high glucose), L (high lard), F (fructose) or GC (high glucose, 0.9% cholesterol). The K_m and V_max. values for transfer from GDP-mannose were virtually indistinguishable in the four preparations.

In the absence of exogenous dolichyl phosphate, the largest amount of transfer of [¹⁴C]mannose into the mannosyl lipid was observed with preparations from fructose-fed animals. Preparations from glucose-fed animals showed about 60% as much transfer, whereas membranes from rats fed the other diets showed intermediate values between the fructose- and glucose-fed animals. The inclusion of cholesterol in the glucose diet elicited an increase in transfer of mannose.

Under conditions of saturating exogenous dolichyl phosphate, preparations from lard-fed animals have 1.5 times as much enzyme activity as do preparations from animals fed the other three diets.

     

Modulation of dolichyl-phosphomannose synthase activity by changes in the lipid environment of the enzyme

Rat liver dolichyl-phosphomannose synthase (GDP mannose-dolicholphosphate mannosyltransferase; EC 2.4.1.83) was previously shown to catalyze optimal rates of mannosyl transfer to dolichyl-P when the polyprenol acceptor was incorporated into a phosphatidylethanolamine (PE) matrix that has a tendency to adopt a nonbilayer (hexagonal HII) phase [Jensen, J. W., & Schutzbach, J. S. (1985) Eur. J. Biochem. 153, 41-48]. The present investigations now further define the properties of the lipid environment that are essential for mannosyltransferase activity. Monogalactosyl diglyceride (MGDG), a glycoglycerolipid that prefers a nonbilayer-phase organization in isolation, was shown to provide a suitable lipid matrix for synthase activity. By comparison, the enzyme was not activated by digalactosyl diglyceride (DGDG), which forms stable bilayer structures upon hydration. Enzyme activity in MGDG/DGDG mixtures decreased as the proportion of DGDG in the dispersion was increased. Although bilayer-forming phospholipids supported low rates of mannosyl transfer, enzyme activity was stimulated by the addition of MGDG to either phosphatidylcholine (PC) or PE/PC (1:1) membranes. The incorporation of agents known to destabilize bilayer structures including dolichols, ubiquinone, dodecane, and cholesterol into PE/PC (1:1) membranes also increased the rate of mannosyl transfer. Enzyme activity in PC membranes was stimulated by the presence of gramicidin and also by greatly increased concentrations of the substrate, dolichyl-P. The results demonstrate that the enzyme does not have a requirement for PE and suggest that the physical state of the lipid matrix is an important determinant for reconstitution of the synthase and polyprenol phosphate substrate in a productive complex. The formation of an enzyme/lipid complex was demonstrated by sucrose density gradient centrifugation and could be correlated with the lipid requirements for enzyme activity.     

Introduction of O-glycosidically linked mannose into proteins via mannosyl phosphoryl dolichol by microsomes from Fusarium soani f. pisi

Cutinase, a glycoprotein containing O-glycosidically linked carbohydrates, is induced in glucose-grown Fusarium solani f. pisi by cutin hydrolysate. Microsomal preparations from the induced cells catalyzed mannosyl transfer from GDP-mannose to glycolipid and glycoprotein fractions but not into oligosaccharide lipids. Maximal rates of mannosyl transfer into glycolipids and glycoproteins were obtained with 5 mm Mg²⁺ and 10 mm Mn²⁺, respectively. Mannosyl transfer into glycolipids and glycoproteins showed pH optima of 8.0 and 7.0, respectively, and both transfers showed an apparent K_m of about 2 μm for GDP-mannose. The mannosyl lipid was identified as β-d-mannosyl phosphoryl dolichol by thinlayer and ion-exchange chromatography, as well as by analyses of the products derived from it by acid and base treatments. The fungal microsomal preparation also catalyzed mannosyl transfer from GDP-mannose to exogenous dolichol phosphate. This transfer was stimulated maximally by 0.09% Triton X-100 and showed a pH optimum at pH 8.0. The apparent K_m values for dolichol phosphate and GDP-mannose were 120 and 2.3 μm, respectively. The product derived from exogenous dolichol phosphate was identified as β-d-mannosyl phosphoryl dolichol as indicated above. The endogenous mannosyl acceptor lipid from this fungus was isolated by DEAE-cellulose chromatography. Analysis of the p-nitrobenzoyl derivatives of the base hydrolysis products of this acceptor lipid by highperformance liquid chromatography showed that the major components of this dolichol were C₉₅ and C₁₀₀. The microsomal preparation also catalyzed the transfer of mannose from exogenous mannosyl phosphoryl dolichol to glycoproteins with a pH optimum of 7.5 and an apparent K_m of 1.7 μm. Analyses of the β-elimination products of the glycoproteins generated from both GDP-mannose and dolichol phosphoryl mannose showed that single mannosyl residues were transferred to hydroxyl groups of the endogenous proteins. Exogenous cutinase was not glycosylated even after denaturation, sulfitolysis, or removal of carbohydrates by HF hydrolysis. Sodium dodecyl sulfate electrophoresis indicated that cutinase and its possible precursors were among the in vitro glycosylation products. Bacitracin and amphomycin but not tunicamycin inhibited the mannosyl transfer reactions.     

Rat liver microsomes catalyse mannosyl transfer from GDP-d-mannose to retinyl phosphate with high efficiency in the absence of detergents

In the absence of detergent, the transfer of mannose from GDP-mannose to rat liver microsomal vesicles was highly stimulated by exogenous retinyl phosphate in incubations containing bovine serum albumin, as measured in a filter binding assay. Under these conditions 65% of mannose 6-phosphatase activity was latent. The transfer process was linear with time up to 5min and with protein concentration up to 1.5mg/0.2ml. It was also temperature-dependent. The microsomal uptake of mannose was highly dependent on retinyl phosphate and was saturable against increasing amounts of retinyl phosphate, a concentration of 15mum giving half-maximal transfer. The uptake system was also saturated by increasing concentrations of GDP-mannose, with an apparent K(m) of 18mum. Neither exogenous dolichyl phosphate nor non-phosphorylated retinoids were active in this process in the absence of detergent. Phosphatidylethanolamine and synthetic dipalmitoylglycerophosphocholine were also without activity. Several water-soluble organic phosphates (1.5mm), such as phenyl phosphate, 4-nitrophenyl phosphate, phosphoserine and phosphocholine, did not inhibit the retinyl phosphate-stimulated mannosyl transfer to microsomes. This mannosyl-transfer activity was highest in microsomes and marginal in mitochondria, plasma and nuclear membranes. It was specific for mannose residues from GDP-mannose and did not occur with UDP-[(3)H]galactose, UDP- or GDP-[(14)C]glucose, UDP-N-acetyl[(14)C]-glucosamine and UDP-N-acetyl[(14)C]galactosamine, all at 24mum. The mannosyl transfer was inhibited 85% by 3mm-EDTA and 93% by 0.8mm-amphomycin. At 2min, 90% of the radioactivity retained on the filter could be extracted with chloroform/methanol (2:1, v/v) and mainly co-migrated with retinyl phosphate mannose by t.l.c. This mannolipid was shown to bind to immunoglobulin G fraction of anti-(vitamin A) serum and was displaced by a large excess of retinoic acid, thus confirming the presence of the beta-ionone ring in the mannolipid. The amount of retinyl phosphate mannose formed in the bovine serum albumin/retinyl phosphate incubation is about 100-fold greater than in incubations containing 0.5% Triton X-100. In contrast with the lack of activity as a mannosyl acceptor for exogenous dolichyl phosphate in the present assay system, endogenous dolichyl phosphate clearly functions as an acceptor. Moreover in the same incubations a mannolipid with chromatographic properties of retinyl phosphate mannose was also synthesized from endogenous lipid acceptor. The biosynthesis of this mannolipid (retinyl phosphate mannose) was optimal at MnCl(2) concentrations between 5 and 10mm and could not be detected below 0.6mm-MnCl(2), when synthesis of dolichyl phosphate mannose from endogenous dolichyl phosphate was about 80% of optimal synthesis. Under optimal conditions (5mm-MnCl(2)) endogenous retinyl phosphate mannose represented about 20% of dolichyl phosphate mannose at 15min of incubation at 37 degrees C.