Enzymatic synthesis of polyprenol monophosphate mannose in insects

Summary The microsomal fraction of insects was found to contain an enzyme which transfers mannose from guanosine diphosphate mannose to an endogenous or exogenous insect lipid and to other acceptors such as dolichol monophosphate or ficaprenol monophosphate. This activity depended on the presence of Triton X-100 and magnesium ions, the optimal concentration of the latter being 10mM. The optimal temperature of the reaction was 25 °C and the maximal activity was obtained at pH 7.9. The mannolipid formed behaved as a monophosphodiester when chromatographed on DEAE-cellulose. Weak acid treatment of the product liberated mannose. Its behaviour both on thin layer and Sephadex G-150 chromatography would indicate the presence of a number of isoprenyl units similar to the dolichol and different from the ficaprenol derivative. Stability to phenol treatment indicated that the lipid fraction of the mannolipid is an±-saturated polyprenol phosphate similar to dolichol monophosphate.Abbreviations DoIMP dolichol monophosphate - FMP ficaprenol monophosphate - IGAL insect glycosyl acceptor lipid Dedicated to ProfessorLuis F. Leloir on the occasion of his 70th birthday.     

INVOLVEMENT OF MANNOSYL-PHOSPHORYL-DOLICHOLS IN MANNOSE TRANSFER TO BRAIN GLYCOPROTEINS

Abstract— Mannose was transferred from GDP-[¹⁴C]mannose by homogenates of embryonic chick and adult rat brain to mannolipids with properties identical to manriosyl-phosphoryl-dihydropolyisoprenols. Embryonic chick brain formed six-fold larger quantities of mannolipid than adult rat brain. The reaction was stimulated by Mn²⁺ ions and Triton X-100 but inhibited by EDTA. Phosphoenolpyruvic acid had no effect on the reaction. A crude mitochondrial fraction was two to three times more active than the microsomal fraction. All radioactivity in the mannolipid could be displaced by the addition of non-radioactive GDP-mannose. The endogenous lipid acceptor in brain was readily labelled in vivo by injection of [³H]mevalonate into the amniotic sac of 7-day-old embryos. The mannolipid formed had the properties of an acidic phospholipid on column and TLC, was stable to dilute alkali but readily cleaved by dilute acid. Synthesis was markedly stimulated by the addition of pig liver or calf brain dolichol phosphate in the presence of Triton X-100 and Mn²⁺. The mannolipid so formed displayed chemical characteristics identical to the endogenous lipid acceptor. Incubation of the purified radioactive mannolipid with the 'post-nuclear' fraction from 14-day-old embryonic chick brain in the presence of EDTA and Triton X-100 resulted in the transfer of 40-50 per cent of the radioactive mannose to protein and 40-45 per cent to water soluble compounds. The efficiency of transfer of radioactivity from endogenously formed mannolipid with or without the addition of dolichol phosphate was similar to exogenously added highly purified mannolipid. These results are compatible with the hypothesis that synthesis of the mannose core of brain glycoproteins involves the synthesis first of mannosyl-phosphoryl-dolichols followed by transfer of the mannose to glycoprotein.     

Enzymatic transfer of mannose from guanosine diphosphate mannose to dolichol phosphate in yeast (Hansenula holstii) A possible step in mannan synthesis

A particulate enzyme fraction isolated from yeast (Hansenula holstii) catalyzes the transfer of mannose from GDPmannose to endogenous lipid acceptors. Kinetic studies are presented which suggest that one of the mannolipids is a precursor to cell wall mannan. The solubility and chromatographic properties, the stability to mild alkali, and the release of mannose by mild acid hydrolysis are characteristic of polyisoprenyl phosphoryl mannose. Addition of dolichol phosphate to the enzyme system stimulates the synthesis of a mannolipid with properties similar to that synthesized from endogenous lipid. That the exogenous dolichol phosphate was acting as a mannosyl acceptor was demonstrated by showing that dolichol [³²P]phosphate was converted to dolichol [³²P]phosphate mannose.     

A mannosyl-carrier lipid of bovine adrenal meddulla and rat parotid.

1. The transfer of mannose from GDP-(U-14-C)mannose into endogenous acceptors of bovine adrenal medullla and rat parotid was studied. The rapidly labelled product, a glycolipid, was partially purified and characterized. 2. It was stable to mild alkaline hydrolysis but yielded (14-C)mannose on mild acid hydrolysis. It co-chromatographed with mannosyl phosphoryl dolichol in four t.l.c. systems and on DEAE-cellulose acetate. Addition of dolichol phosphate or a dolichol phosphate-enriched fraction prepared from pig liver stimulated mannolipid synthesis. 3. The formation of mammolipid appeared reversible, since addition of GDP to a system synthesizing the mannolipid caused a rapid loss of label from the mannolipid. UDP-N-acetylglucosamine did not inhibit mannolipid synthesis except at high concentrations (2 mM), even though in the absence of GDP-mannose, N-acetylglucosamine was incorporated into a lipid having the properties of a glycosylated polyprenyl phosphate. 4. Mannose from GDP-mannose was also incorporated into two other acceptors, (2y being insoluble in chloroform-methanol (2:1, v/v) but soluble in choloroform-methanol-water (10:10:3, by vol.) and (ii) protein. These are formed much more slowly than the mannolipid. 5. Exogenous mannolipid served as a mannose donor for acceptors (i) and (ii), and it is suggested that transfer of mannose from GDP-mannose to mannosylated protein occurs via two intermediates, the mannolipid and acceptor (i).     

EVIDENCE FOR THE BIOSYNTHESIS OF MANNOSYLPHOSPHORYLDOLICHOL AND N-ACETYLGLUCOSAMINYLPYROPHOSPHORYLDOLICHOL BY AN AXOLEMMA-ENRICHED MEMBRANE PREPARATION FROM BOVINE WHITE MATTER

An axolemma-enriched membrane fraction prepared by an improved procedure from bovine white matter catalyzes the enzymatic transfer of [¹⁴C]mannose and N-acetyl[¹⁴C]glucosamine from their nucleotide derivatives into a mannolipid and an N-acetylglucosaminyl lipid in the presence of exogenous dolichyl monophosphate. The labeled glycolipid products have the chemical and chromatographic characteristics of mannosylphosphoryldolichol and N-acetylglucosaminylpyrophosphoryldolichol. The initial rates of synthesis of the glycolipids by the axolemma-enriched membrane fraction have been compared with the initial rates of glycolipid formation catalyzed by a microsomal preparation and myelin in the presence or absence of dolichyl monophosphate. Essentially no glycolipid synthesis was observed when either GDP-[¹⁴C]mannose or UDP-N-acetyl[¹⁴C]glucosamine were incubated with myelin in the presence or absence of exogenous dolichyl monophosphate. A comparison of the initial rates of synthesis of the glycolipids using endogenous acceptor lipid revealed that the rate of formation of mannolipid was 7 times faster for the microsomal membranes than the axolemma-enriched membranes. In the presence of an amount of dolichyl monophosphate approaching saturation the initial rate of glycolipid synthesis was markedly enhanced for both membrane preparations. However, due to a more dramatic enhancement in the axolemma-enriched membranes the initial rate of mannolipid synthesis was only approx. 2.5 times greater in the microsomal membranes. A similar observation was made when the initial rates of N-acetylglucosaminyl lipid synthesis were compared for axolemma-enriched and microsomal preparations in the presence and absence of exogenous dolichyl monophosphate. These studies indicate that the axolemma-enriched membranes have a relatively lower content of dolichyl monophosphate than the microsomal membranes although the difference in the amount of mannosyltransferase is only two to three-fold lower. The presence of a sugar nucleotide pyrophosphatase activity capable of degrading GDP-mannose and UDP-N-acetylglucosamine has also been demonstrated in the axolemma-enriched membrane fraction.     

The transfer of mannose from guanosine diphosphate mannose to dolichol phosphate and protein by pig liver endoplasmic reticulum

When pig liver microsomal preparations were incubated with GDP-[¹⁴C]mannose, 10–40% of the ¹⁴C was transferred to mannolipid and 1–3% to mannoprotein. The transfer to mannolipid was readily reversible and GDP was one of the products of the reaction. It was possible to reverse the reaction by adding excess of GDP and to show the incorporation of [¹⁴C]GDP into GDP-mannose. When excess of unlabelled GDP-mannose was added to a partially completed incubation there was a rapid transfer back of [¹⁴C]mannose from the mannolipid to GDP-mannose. The other product of the reaction, the mannolipid, had the properties of a prenol phosphate mannose. This was illustrated by its lability to dilute acid but stability to dilute alkali, and by its chromatographic properties. Dolichol phosphate stimulated the incorporation of [¹⁴C]mannose into both mannolipid and into protein, although the former effect was larger and more consistent than the latter. The incorporation of exogenous [³H]dolichol phosphate into the mannolipid, and its release, accompanied by mannose, on treatment of the mannolipid with dilute acid, confirmed that exogenous dolichol phosphate can act as an acceptor of mannose in this system. It was shown that other exogenous polyprenol phosphates (but not farnesol phosphate or cetyl phosphate) can substitute for dolichol phosphate in this respect but that they are much less efficient than dolichol phosphate in stimulating the transfer of mannose to protein. Since pig liver contained substances with the chromatographic properties of both dolichol phosphate and dolichol phosphate mannose, which caused an increase in transfer of [¹⁴C]mannose from GDP-[¹⁴C]mannose to mannolipid, it was concluded that endogenous dolichol phosphate acts as an acceptor of mannose in the microsomal preparation. The results indicate that the mannolipid is an intermediate in the transfer of mannose from GDP-mannose to protein. Some 4% of the mannose of a sample of mannolipid added to an incubation was transferred to protein. A scheme is proposed to explain the variations with time in the production of radioactive mannolipid, mannoprotein, mannose 1-phosphate and mannose from GDP-[¹⁴C]mannose that takes account of the above observations. ATP, ADP, UTP, GDP, ADP-glucose and UDP-glucose markedly inhibited the transfer of mannose to the mannolipid.     

The involvement of endogenous dolichol in the formation of lipid-linked precursors of glycoprotein in rat liver

Endogenous dolichol was shown to function as a natural acceptor of mannose residues by using regenerating rat liver containing [(3)H]dolichol. When subcellular fractions from this liver were incubated with GDP-[(14)C]mannose a double-labelled lipid, which represented 30% of the total [(14)C]mannolipid, could be isolated. This lipid was shown to be identical with the dolichol phosphate mannose formed from exogenous dolichol phosphate, by chromatography, stability to alkali and by chemical cleavage to mannose and dolichol derivatives. It was formed by the rough endoplasmic reticulum and mitochondria. If it is concerned in glycoprotein synthesis this would suggest that it functions in the formation of both secreted and mitochondrial glycoproteins. When both the dolichol and retinol of rat tissue were radioactive they made similar contributions to the synthesis of the lipid by liver microsomal fractions and intestinal epithelial cells.     

Evidence for the stimulation of dolichol and mannolipid synthesis by glucocorticoids in HeLa cells.

The effects of addition of 1 microM-dexamethasone on the rate of transfer of mannose from GDP-mannose into mannolipid have been studied in HeLa cell cultures. Concurrent with an increase in incorporation of mannose into glycoproteins, the incorporation of mannose from GDP-mannose in vitro into mannolipid and dolichol-linked oligosaccharides was increased after dexamethasone treatment. Stimulation of mannolipid synthesis showed a correlation with the 11 beta, 17 alpha, 21-trihydroxy structure of C21 steroids. Dexamethasone treatment also resulted in an increased incorporation of acetate into dolichol and dolichyl phosphate. The results suggest that the effect of dexamethasone on the cell-surface glycoprotein accumulation is related to increased sugar-linked dolichol synthesis.     

Glycoprotein biosynthesis in Chlamydomonas. A mannolipid intermediate with the properties of a short-chain alpha-saturated polyprenyl monophosphate

A crude membrane preparation of the unicellular green alga Chlamydomonas reinhardii was found to catalyse the incorporation of D-[14C]mannose from GDP-D-[14C]-mannose into a chloroform/methanol-soluble compound and into a trichloroacetic acid-insoluble polymer fraction. The labelled lipid revealed the chemical and chromatographic properties of a short-chain (about C55-C65) alpha-saturated polyprenyl mannosyl monophosphate. In the presence of detergent both long-chain (C85-C105) dolichol phosphate and alpha-unsaturated undecaprenyl phosphate (C55) were found to be effective as exogenous acceptors of D-mannose from GDP-D-[14C]mannose to yield their corresponding labelled polyprenyl mannosyl phosphates. Exogenous dolichyl phosphate stimulated the incorporation of mannose from GDP-D-[14C]mannose into the polymer fraction 5-7-fold, whereas the mannose moiety from undecaprenyl mannosyl phosphate was not further transferred. Authentic dolichyl phosphate [3H]mannose and partially purified mannolipid formed from GDP-[14C]mannose and exogenous dolichyl phosphate were found to function as direct mannosyl donors for the synthesis of labelled mannoproteins. These results clearly indicate the existence of dolichol-type glycolipids and their role as intermediates in transglycosylation reactions of this algal system. Both the saturation of the alpha-isoprene unit and the length of the polyprenyl chain may be regarded as evolutionary markers.     

Formation of polyprenol-linked mono- and oligosaccharides in Phaseolus aureus

A crude membrane preparation from Phaseolus aureus hypocotyls catalyzes the incorporation of mannose from GDP-[¹⁴C]mannose into a acid labile glycolipid and a methanol insoluble fraction. Addition of dolichyl monophosphate to the incubation mixture stimulated the formation of both the mannolipid and the methanol insoluble endproduct. Thin-layer chromatography of endogenous lipid and of the stimulated lipid fraction revealed that both compounds run identical. Ficaprenyl monophosphate also stimulates the incorporation of mannose; however, the ficaprenyl monophosphate mannose formed is not identical to the endogenous mannolipid. This suggests that the endogenous acceptor has the properties of an α-saturated polyprenyl monophosphate rather than those of the ficaprenyl phosphate type. The same membrane preparation also incorporates N-acetylglucosamine into an acid labile glyolipid as well as into a polymer fraction. Evidence is presented that the N-acetylglucosamine containing lipid consists of a mixture of dolichyl pyrophosphate N-acetylglucosamine and dolichyl pyrophosphate di-N-acetylchitobiose. It seems likely that the two compounds have a precursor-product relationship. Incubation of dolichyl pyrophosphate di-N-acetylchitobiose together with GDP-mannose gives rise to lipid-bound mannosyl-di-N-acetylchitobiose. Radioactivity from either the [¹⁴C]mannolipid or the N-acetyl[¹⁴C]glucosamine containing lipid is incorporated into a methanol insoluble product to 3.4 and 6.3%, respectively; it seems, at least in part, to be a glycoprotein.     

Novel mannose carrier in the trypanosomatid Crithidia fasciculata behaving as a short alpha-saturated polyprenyl phosphate.

Crithidia fasciculata cells incubated with [14C]glucose or membranes derived from the same protozoan incubated with GDP-[14C]mannose were found to synthesize a lipid monophosphate mannose. No glucosylated mild acid-labile compound was formed in vivo or in vitro when UDP-[14C]glucose was used instead of GDP-[14C]mannose. The lipid moiety of the mannosyl derivative formed behaved as a polyprenol having 11 isoprene residues as judged by t.l.c. and be gel filtration in sodium deoxycholate-containing buffers. The mannolipid was not broken on treatment with hot phenol, suggesting the existence of an alpha-saturated isoprene unit. This is the first case reported in which a mannosyl phospholipid involved in sugar transfer in a eukaryotic cell behaves as if it was similar to that of bacterial polyprenols, although having its putative alpha-isoprene unit saturated to the same extent as dolichols from higher organisms.     

Synthesis of polyprenol-monophosphate-β-galactose by Acetobacter xylinum

Summary A particulate enzyme preparation fromAcetobacter xylinum synthesizes ficaprenol-monophosphate--galactose from ficaprenol monophosphate (FMP) and UDP-galactose in the presence of detergent. The product has the same properties as those previously reported for the compound formed with the endogenous acceptor. Dolichol-monophosphate (DolMP) is also a good galactose acceptor but the product obtained has different properties. Lipid extracts fromAcetobacter contain galactose acceptor capacity which is lost by mild acid treatment. FMP behaves in a similar manner but DolMP is resistant to this treatment. It is concluded that the endogeneous acceptor is an allylic phosphate ester of a polyprenol.Abbreviations FMP ficaprenol monophosphate - DolMP dolichol monophosphate Dedicated to ProfessorLuis F. Leloir on the occasion of his 70^th birthday.     

Role of mannosyl phosphoryl polyisoprenol in biosynthesis of mammary glycoproteins

When a membrane preparation from the lactating bovine mammary gland is incubated with GDP-[¹⁴C] mannose, mannose is incorporated into a [¹⁴C] mannolipid, a [Man-¹⁴C] oligosaccharide-lipid, and metabolically stable endogenous acceptor(s). The rate of mannosyl incorporation is the fastest into [¹⁴C] mannolipid, intermediate in [Man-¹⁴C] oligosaccharide-lipid, and least into [Man-¹⁴C] endogenous acceptor(s). The [¹⁴C] mannolipid has been partially purified and characterized. Mild acid hydrolysis of this compound gives [¹⁴C] mannose, whereas alkaline hydrolysis yielded [¹⁴C] mannose phosphate as the labeled product. The t_½ of hydrolysis of the mannolipid under the acidic and basic conditions are comparable to values obtained for mannosyl phosphoryl dolichol in other systems. The mannolipid is chromatographically indistinguishable from calf brain mannosyl phosphoryl polyisoprenol and chemically synthesized β-mannosyl phosphoryl dolichol. Exogenous dolichol phosphate stimulates the synthesis of mannolipid in mammary particulate preparations 8.5-fold. Synthesis of mannolipid is freely reversible; in the presence of GDP, the transfer of mannosyl moiety from endogenously labeled mannolipid to GDP-mannose is obtained. All of these results indicate that the structure of mannolipid is mannosyl phosphoryl polyisoprenol. Even though the precise chain length of the polyisoprenol portion has not been established, it is tentatively suggested to be dolichol. Partially purified [¹⁴C] mannolipid can directly serve as a mannosyl donor in the synthesis of [Man-¹⁴C] oligosaccharide-lipid and [Man-¹⁴C] endogenous acceptor(s). Pulse and chase kinetics utilizing GDP-mannose to chase the mannosyl transfer from GDP-[¹⁴C] mannose in the mammary membrane incubations caused an immediate and rapid turnover of [¹⁴C] mannose from [¹⁴C] mannolipid while the incorporation of label in [Man-¹⁴C] oligosaccharide-lipid and radioactive endogenous acceptor(s) continued for a short period before coming to a halt. Both gel filtration and electrophoresis indicate that the endogenous acceptor(s) are a mixture of 2 or more glycoproteins since incubation with proteases releases all of the radioactivity into water soluble low-molecular-weight components, perhaps glycopeptides. All of the above evidence is consistent with the following precursor-product relationship: GDP-mannose ? mannosyl phosphoryl polyisoprenol → mannosyl-oligosaccharide-lipid → mannosyl-proteins. The exact structure of the oligosaccharide-lipid and the endogenous glycoproteins is unknown.     

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.     

Formation of lipid-bound oligosaccharides in yeast

Incubation of a membrane fraction from Saccharomyces cerevisiae with UDP-N-acetyl [¹⁴C] glucosamine catalyzes the tranfer of N-acetylglucosamine to an endeenous lipid fraction as well as a methanol-insoluble polymer. The glycolipid was shown to separate into three compounds by thin-layer chromatography. The biosynthesis of two of them could clearly be stimulated by the addition of dolichol monophosphate to the incubation mixture. Evidence is presented that the substances are dolichol pyrophosphate derivatives: dolichol pyrophosphate N-acetylglucosamine and dolichol pyrophosphate di-N-acetylchitobiose. The formation of the chitobiose-containing lipid was increased by reincubation of the glycolipid with non-radioactive UDP-N-acetylglucosamine.The same particulate preparation transferred mannose from GDPmannose to dolichol pyrophosphate di-N-acetylchitobiose, giving rise to a lipid-bound oligosaccharide. Molecular weight determination of the oligosaccharide moiety gave a value of 780, which is consistent with a tetrasaccharide containing two mannose subunits attached to di-N-acetylchitobiose.The methanol-insoluble radioactive product obtained in the presence of UDP-N-acetyl[¹⁴C]glucosamine was transformed by pronase treatment to a large extent into dialyzable material. It is suggested that the glycolipids described serve as intermediates in the glycosylation of yeast mannoproteins.     

A developmental change in dolichyl phosphate mannose synthase activity in pig brain

The initial rate of dolichyl phosphate mannose biosynthesis was measured in white-matter membranes from pig brain at various ages from before birth throughout the period of most rapid brain development. Dolichyl phosphate mannose synthase activity increased from prenatal values to a maximum in 3 week-old animals, and gradually decreased to adult values after 8 weeks of age. The nature of the developmental change was investigated by enzymic and biochemical comparisons of the membrane preparations from the most active age (3 weeks) and adult controls. The specific activity of dolichyl phosphate mannose synthase in preparations from actively myelinating animals was approx. 3-fold higher than adults when mannolipid formation was assayed with saturating concentrations of GDP-[¹⁴C]mannose and utilizing only endogenous acceptor lipid. No major variations were found in the apparent K_m values for GDP-mannose or exogenous dolichyl monophosphate. However, the ratio of dolichyl phosphate mannose synthase activity for myelinating animals/adult animals decreased significantly when large amounts of exogenous dolichyl monophosphate were added to the incubation mixtures. Dolichyl phosphate mannose synthase activity was also compared in white-matter membranes depleted of endogenous dolichyl monophosphate by enzymic mannosylation or treatment with butanol. When these preparations were assayed with identical amounts of exogenous dolichyl monophosphate, the dolichyl monophosphate-depleted membranes from actively myelinating animals contained only 20–30% more dolichyl phosphate mannose synthase activity. Overall, these studies strongly suggest that the developmental change in dolichyl phosphate mannose synthase activity is due primarily to the presence of a relatively lower amount of endogenous dolichyl monophosphate being accessible to the mannosyltransferase in the white-matter membranes from adult animals.     

Dolichol kinase activity: a key factor in the control of N-glycosylation in inner mitochondrial membranes

Inner mitochondrial membranes from liver contain a dolichol kinase which required CTP as a phosphoryl donor. Kinase activity was linear with protein concentration and unlike other reported kinases, activated almost equally well by Mg2+, Mn2+ or Ca2+. Thin-layer chromatography showed that the reaction product co-migrated with authentic dolichyl monophosphate. The phosphorylation of dolichol did not occur in presence of ATP, GTP or UTP but required exogenous dolichol for maximal activity. Newly synthesized [3H]dolichyl monophosphate has been shown to be glycosylated in the presence of GDP[14C]mannose or UDP[14C]glucose. The double labeled lipids formed by the sugar nucleotide-dependent reactions were identified respectively as [14C]mannosylphosphoryl[3H]dolichol and [14C]glucosylphosphoryl [3H]dolichol. These results are discussed in terms of regulation of N-glycosylation processes in inner mitochondrial membranes from liver.     

Biosynthesis of glycoproteins in Candida albicans: Solubilization and partial characterization of dolichol phosphate mannose synthase and protein mannosyl transferases

Incubation of a mixed membrane fraction isolated from C. albicans yeast cells with Nonidet P-40 at a detergent/protein ratio as low of 0.025 (0.016–0.019%, w/v) yielded a soluble fraction that catalyzed the transfer of mannose from GDP-[¹⁴C] Man into dolichol phosphate mannose and from this intermediate into mannoproteins. Over 95% of the sugar in mannoproteins was O-linked as judged from its release after -elimination. Mannose was identified as the sole product after this treatment. Transfer activity did not depend on exogenous lipid acceptor indicating that the latter was solubilized along with the mannosyl transferases. Synthesis of mannolipid and mannoproteins occurred at optima temperatures of 20 °C and 37 °C, respectively, and at a pH in the range of 7.5-9.5. Mannosyl transfer into the mannolipid was stimulated by Mg²⁺and inhibited by Ca²⁺and Mn²⁺whereas mannoprotein labeling was stimulated by Mn²⁺and to a lower extent by Mg²⁺. When measured as a function of substrate concentration, the synthesis of the mannolipid was a nearly linear function of GDP-Man concentration in the range of 5 to 32 M whereas protein mannosylation exhibited hyperbolic kinetics with saturation reached at about 10 M. The solubilized preparation was able to utilize an exogenous source of mannolipid as sugar donor for protein mannosylation. Dinucleotides and, to a higher extent trinucleotides, inhibited mannosyl transfer into the mannolipid and hence into mannoproteins.     

Dolichol phosphate is a rate-limiting factor in mannosyl transferase activity of adult male worms of Schistosoma mansoni

The formation of mannolipid through catalysis by mannosyl transferase of adult females of Schistosoma mansoni was found to be 2-3 fold higher than male worms. In contrast, mannosyl transferase in immature females generated approximately the same amount of mannolipid as male worms, immature or not. Exogenous dolichol phosphate added to homogenates of male worms produced a stoichiometric increase in mannolipid formation. Saturating amounts of dolichol phosphate generated similar mannosyl transferase activities in male and female homogenates, showing that in S. mansoni, dolichol phosphate is the lipid intermediate in the glycosylation reaction and that this mannolipid is a rate-limiting substrate. Thin layer chromatography revealed that the mannolipid was identical in male and female worms. Adult males incubated with ¹⁴C-acetate synthesised several apolar compounds, one of which displayed a R_f identical to that of the mannolipid. When exposed to ¹⁴C-acetate treated males in vitro, untreated females were able to incorporate a compound, which partitioned in the same way as the mannolipid. The increased mannosyl transferase-dependent mannolipid formation in adult females may reflect a higher energy demand by these parasites, which is probably associated with oogenesis.     

Glucomannan Biosynthesis Catalyzed by Pisum sativum Enzymes

The results of molecular weight studies, structural analysis of the [(14)C]polysaccharides, and enzymic properties indicate that the Pisum sativum guanosine diphosphosphate glucose: glucosyltransferase is an enzymic component involved in the biosynthesis of glucomannan chains. The properties of the Pisum sativum particulate enzyme are essentially identical to the glucomannan synthetase obtained from Phaseolus aureus. Also present in the particulate preparation is an enzyme which catalyzes the formation of a [(14)C]mannolipid, using guanosine diphosphate-[(14)C]mannose as a substrate. The [(14)C]mannolipid is hydrolyzed by treatment with 0.012 m HCl, but is stable to treatment with 0.09 m NaOH. The formation of the [(14)C]mannolipid is apparently reversed by guanosine diphosphate, but not by guanosine monophosphate. The chromatographic mobility of the [(14)C]mannolipid is identical to that of a similar mannolipid synthesized by a Phaseolus aureus enzyme.