Synthesis of retinyl phosphate mannose and dolichyl phosphate mannose from endogenous and exogenous retinyl phosphate and dolichyl phosphate in microsomal fraction. Specific decrease in endogenous retinyl phosphate mannose synthesis in vitamin A deficiency.

Rat liver microsomal fraction synthesized Ret-P-Man (retinyl phosphate mannose) and Dol-P-Man (dolichyl phosphate mannose) from endogenous Ret-P (retinyl phosphate) and Dol-P (dolichyl phosphate). Ret-P-Man synthesis displayed an absolute requirement for a bivalent cation, and also Dol-P-Man synthesis was stimulated by bivalent metal ions. Mn2+ and Co2+ were the most active, with maximum synthesis of Ret-P-Man occurring at 5-10 mM: Mg2+ was also active, but at higher concentrations. At 5mM-Mn2+ the amount of endogenous Ret-P mannosylated in incubation mixtures containing 5 microM-GDP-mannose in 15 min at 37 degrees C was approx. 3 pmol/mg of protein. In the same assays about 7-10 pmol of endogenous Dol-P was mannosylated. Bivalentcation requirement for Ret-P-Man synthesis from exogenous Ret-P showed maximum synthesis at 2.5 mM-Mn2+ or -Co2+. In addition to Ret-P-Man and Dol-P-Man, a mannolipid co-chromatographing with undecaprenyl phosphate mannose was detected. Triton X-100 (0.5%) abolished Ret-P-Man synthesis from endogenous Ret-P and caused a 99% inhibition of Ret-P-Man synthesis from exogenous Ret-P. The presence of detergent (0.5%) also inhibited Dol-P-Man synthesis from endogenous Dol-P and altered the requirement for Mn2+. Microsomal fraction from Syrian golden hamsters was also active in Ret-P-Man and Dol-P-Man synthesis from endogenous Ret-P and Dol-P. At 5 mM-Mn2+ about 2.5 pmol of endogenous Ret-P and 3.7 pmol of endogenous Dol-P were mannosylated from GDP-mannose per mg of protein in 15 min at 37 degrees C. On the other hand, microsomal fraction from vitamin A-deficient hamsters contained 1.2 pmol of Ret-P and 14.1 pmol of Dol-P available for mannosylation. Since GDP-mannose: Ret-P and GDP-mannose: Dol-P mannosyltransferase activities were not affected, depletion of vitamin A must affect Ret-P and Dol-P pools in opposite ways.     

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.     

Mannosylation of endogenous and exogenous phosphatidic acid by liver microsomal membranes. Formation of phosphatidylmannose

Hamster liver post-nuclear membranes catalyze the transfer of mannose from GDP-mannose to endogenous dolichyl phosphate and to a second major endogenous acidic lipid. This mannolipid was believed to be synthesized from endogenous retinyl phosphate and was tentatively identified as retinyl phosphate mannose (Ret-P-Man) (De Luca, L. M., Brugh, M. R. Silverman-Jones, C. S. and Shidoji, Y. (1982) Biochem. J. 208, 159-170). To characterize this endogenous mannolipid in more detail, we isolated and purified the mannolipid from incubations containing hamster liver membranes and GDP-[14C]mannose and compared its properties to those of authentic Ret-P-Man. We found that the endogenous mannolipid was separable from authentic Ret-P-Man on a Mono Q anion exchange column, did not exhibit the absorbance spectrum characteristic of a retinol moiety, and was stable to mild acid under conditions which cleave authentic Ret-P-Man. The endogenous mannolipid was sensitive to mild base hydrolysis and mannose was released from the mannolipid by snake venom phosphodiesterase digestion. These properties were consistent with the endogenous acceptor being phosphatidic acid. Addition of exogenous phosphatidic acid, but not phospholipids with a head group blocking the phosphate moiety, to incubations containing hamster liver membranes and GDP-[14C]mannose resulted in the synthesis of a mannolipid with chromatographic and physical properties identical to the endogenous mannolipid. A double-labeled mannolipid was synthesized in incubations containing hamster liver membranes, GDP-[14C]mannose, and [3H]phosphatidic acid. Mannosyl transfer to exogenous phosphatidic acid was saturable with increasing concentrations of phosphatidic acid and GDP-mannose and specific for glycosyl transfer from GDP-mannose. Class E Thy-1-negative mutant mouse lymphoma cell membranes, which are defective in dolichyl phosphate mannose synthesis, also fail to transfer mannose from GDP-mannose to exogenous phosphatidic acid or retinyl phosphate. Amphomycin, an inhibitor of dolichyl phosphate mannose synthesis, blocked mannosyl transfer to the endogenous lipid, and to exogenous retinyl phosphate and phosphatidic acid. We conclude that the same mannosyltransferase responsible for dolichyl phosphate mannose synthesis can also utilize in vitro exogenous retinyl phosphate and phosphatidic acid as well as endogenous phosphatidic acid as mannosyl acceptors.     

Subcellular localization of the enzyme that forms mannosyl retinyl phosphate from guanosine diphosphate [14C]mannose and retinyl phosphate.

The subcellular distribution of the enzyme catalysing the conversion of retinyl phosphate and GDP-[14C]mannose into [14C]mannosyl retinyl phosphate was determined by using subcellular fractions of rat liver. Purity of fractions, as determined by marker enzymes, was 80% or better. The amount of mannosyl retinyl phosphate formed (pmol/min per mg of protein) for each fraction was: rough endoplasmic reticulum 0.48 +/- 0.09 (mean +/- S.D.); smooth membranes (consisting of 60% smooth endoplasmic reticulum and 40% Golgi apparatus), 0.18 +/- 0.03; Golgi apparatus, 0.13 +/- 0.03; and plasma membrane 0.02.     

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.     

Quantitative assay and subcellular distribution of enzymes acting on dolichyl phosphate in rat liver

To establish on a quantitative basis the subcellular distribution of the enzymes that glycosylate dolichyl phosphate in rat liver, preliminary kinetic studies on the transfer of mannose, glucose, and N-acetylglucosamine-1-phosphate from the respective (14)C- labeled nucleotide sugars to exogenous dolichyl phosphate were conducted in liver microsomes. Mannosyltransferase, glucosyltransferase, and, to a lesser extent, N- acetylglucosamine-phosphotransferase were found to be very unstable at 37 degrees C in the presence of Triton X-100, which was nevertheless required to disperse the membranes and the lipid acceptor in the aqueous reaction medium. The enzymes became fairly stable in the range of 10-17 degrees C and the reactions then proceeded at a constant velocity for at least 15 min. Conditions under which the reaction products are formed in amount proportional to that of microsomes added are described. For N- acetylglucosaminephosphotransferase it was necessary to supplement the incubation medium with microsomal lipids. Subsequently, liver homogenates were fractionated by differential centrifugation, and the microsome fraction, which contained the bulk of the enzymes glycosylating dolichyl phosphate, was analyzed by isopycnic centrifugation in a sucrose gradient without any previous treatment, or after addition of digitonin. The centrifugation behavior of these enzymes was compared to that of a number of reference enzymes for the endoplasmic reticulum, the golgi complex, the plasma membranes, and mitochondria. It was very simily to that of enzymes of the endoplasmic reticulum, especially glucose-6-phosphatase. Subcellular preparations enriched in golgi complex elements, plasma membranes, outer membranes of mitochondira, or mitoplasts showed for the transferases acting on dolichyl phosphate relative activities similar to that of glucose- 6-phosphatase. It is concluded that glycosylations of dolichyl phosphate into mannose, glucose, and N-acetylglucosamine-1-phosphate derivatives is restricted to the endoplasmic reticulum in liver cells, and that the enzymes involved are similarly active in the smooth and in the rough elements.     

Retinyl phosphate mannose synthesis in rat liver membranes. Phospholipase sensitivity and phospholipid requirement.

A remarkable and immediate decrease in GDP-mannose:retinyl phosphate mannosyltransferase activity was found on pre-incubation of rat liver postnuclear membranes with phospholipase A2 or phospholipase C. Under the same conditions of pre-incubation (1 min at 37 degrees C) trypsin did not affect the enzyme activity, whereas pre-incubation for 30 min with trypsin and Pronase abolished enzyme activity. The lipid extract of untreated rat liver membranes partially restored enzyme activity after phospholipase treatment. Sphingomyelin was as active as the endogenous lipids. Other phospholipids were less active in the following order: phosphatidylcholine greater than phosphatidylethanolamine greater than phosphatidylinositol = phosphatidylserine. Dolichyl phosphate mannose synthesis was inhibited less (33%) by phospholipase C than was Ret-P-Man synthesis (98.5%) under identical conditions of incubation, which included 0.025% Triton. However, retinyl phosphate mannose synthesis by purified endoplasmic reticulum was found to be resistant to phospholipase C. Mixing experiments failed to demonstrate an inhibitory effect of the phospholipase-treated postnuclear membrane fraction on the synthetic activity of the endoplasmic reticulum, thus excluding the release of an inhibitory factor from the postnuclear membranes.     

Glycoprotein biosynthesis: studies on thyroid mannosyltransferases. II. Characterization of a polyisoprenyl mannosyl phosphate and evaluation of its intermediary role in the glycosylation of exogenous acceptors

The transfer of mannose from GDP-mannonse to exogenous glycopeptides and simple glycosides has been shown to be carried out by calf thyroid particles (Adamany, A. M., and Spiro, R. G. (1975) J. Biol. Chem. 250, 2830-2841). The present investigation indicates that this mannosylation process is accomplished through two sequential enzymatic reactions. The first involves the transfer of mannose from the sugar nucleotide to an endogenous acceptor to form a compound which has the properties of dolichyl mannosyl phosphate, while in the properties of dolichyl mannosyl phosphate, while in the second reaction this mannolipid serves as the glycosyl donor to exogenous acceptors. The particle-bound enzyme which catalyzed the first reaction utilized GDP-mannose (Km = 0.29 microM) as the most effective mannosyl donor, required a divalent cation, preferably manganese or calcium, and acted optimally at pH 6.3. Mannolipid synthesis was reversed by addition of GDP and a ready exchange of the mannose moiety was observed between [14C]mannolipid and unlabeled GDP-mannose. Exogenously supplied dolichyl phosphate, and to a lesser extent ficaprenyl phosphate, served as acceptors for the transfer reaction. The 14C-labeled endogenous lipid had the same chromatographic behavior as synthetic dolichyl mannosyl phosphate and enzymatically mannosylated dolichyl phosphate. The mannose component in the endogenous lipid was not susceptible to reduction with sodium borohydride and was released by mild acid hydrolysis. Alkaline treatment of the mannolipid released a phosphorylated mannose with properties consistent with that of mannose 2-phosphate. The formation of this compound which can arise from a cyclic 1,2-phosphate indicated, on the basis of steric considerations, that the mannose is present in beta linkage to the phosphate of the lipid. An intermediate role of the mannolipid in the glycosylation of exogenous acceptors was suggested by the observation that addition of dolichyl phosphate to thyroid particles resulted in a marked enhancement of mannose transfer from GDP-mannose to methyl-alpha-D-mannopyranoside acceptor while the presence of the glycoside caused a decrease in the mannolipid level. The glycosyl donor function of the polyisoprenyl mannosyl phosphate in the second reaction of the mannosylation sequence could be directly demonstrated by the transfer of [14C]mannose from purified endogenous mannolipid to either methyl-alpha-D-mannoside or dinitrophenyl unit A glycopeptides by thyroid enzyme in the presence of Triton X-100. The mannosylation of the glycoside was not inhibited by EDTA whereas the transfer of mannose to glycopeptide was cation-dependent. While dolichyl [14C]mannosyl phosphate, prepared from exogenous dolichyl phosphate, served as a donor of mannose to exogenous acceptor, this function could not be fulfilled by ficaprenyl [14C]mannosyl phosphate. The two-step reaction sequence carried out by thyroid enzymes which leads to the formation of an alpha-D-manno-pyranosyl-D-mannose linkage in exogenous acceptors by transfer of mannose from GDP-mannose through a beta-linked intermediate appears to involve a double inversion of anomeric configuration of this sugar.     

The role of vitamin A in the glycosylation reactions of glycoprotein synthesis in an ''in vitro'' system.

Microsomal membrane preparations from rat livers, when incubated with labelled sugar-nucleotides, were shown to synthesize labelled oligosaccharide-lipids in the presence of excess exogenous dolichyl phosphate. Under the incubation conditions defined in the present study, dolichyl pyrophosphoryl(DolPP)GlcNAc2-Man5, DolPPGlcNAc2Man9 and DolPPGlcNAc2Man9Glc3 were the principal oligosaccharide-lipids formed by both control and vitamin A-deficient membranes. However, deficient membranes synthesized 3.2 +/- 0.8 times as much oligosaccharide-lipids and 2.6 +/- 0.7 times as much dolichyl phosphate mannose (DolPMan) and dolichyl phosphate glucose (DolPGlc) as the controls. The transfer of the oligosaccharide chain from the dolichol carrier to the endogenous protein acceptors in vitamin A-deficient microsomes (microsomal fractions) was only 57.5 +/- 9.5% of that of controls. After endo-beta-N-acetylglucosaminidase treatment, only one oligosaccharide species was isolated from both control and vitamin A-deficient microsomal glycoproteins, and was characterized as GlcNAcMan9Glc3. We conclude that the decreased incorporation of labelled mannose and glucose from sugar-nucleotides into the glycoproteins must be due to decreased transfer of GlcNAc2Man9Glc3 from the dolichol carrier to the protein acceptors. This conclusion was further substantiated by the finding that control membranes transferred 4-6 times as much labelled oligosaccharides from exogenously added dolichol-linked substrate (DolPPGlcNAc2Man9Glc3) to endogenous microsomal protein acceptors as compared with the vitamin A-deficient membranes. Attempts to reverse this defect by addition of retinol or retinyl phosphate (a source of retinyl phosphate mannose) to the incubations were unsuccessful.     

The conversion of exogenous retinol and related compounds into retinyl phosphate mannose by adult Brugia pahangi in vitro.

Adult Brugia pahangi took up and incorporated beta-carotene and free retinol in vitro. The uptake of retinol was 50 times greater than that of beta-carotene under similar incubation conditions. beta-Carotene was almost entirely metabolized, primarily to retinol. The metabolism of retinol by B. pahangi in vitro was less extensive, with a variety of retinoids tentatively identified, including retinyl phosphate (Ret-P), retinyl phosphate mannose (Ret-P-Man) and anhydroretinol as minor metabolites. B. pahangi microsomes were also shown to biosynthesize Ret-P-Man from exogenous Ret-P and GDP-mannose, but not from endogenous lipid acceptors alone. In this circumstance an unidentified lipid appeared to be mannosylated by B. pahangi. The rate of mannose transfer to exogenous Ret-P by B. pahangi microsomes was 150 pmol X min -1. (mg of protein) -1. Ret-P-Man synthetase activity from both B. pahangi and rat liver microsomes had an absolute requirement for bovine serum albumin and MnCl2, and occurred in the absence of detergent. The results suggest a biochemical role for vitamin A in B. pahangi, possibly in filarial glycoprotein synthesis.     

Enzymatic synthesis of mannosyl retinyl phosphate from retinyl phosphate and guanosine diphosphate mannose.

A study was conducted to determine whether retinyl phosphate would act as substrate for the enzymatic synthesis of mannosyl retinyl phosphate. Retinyl phosphate, prepared chemically, supported the growth of vitamin A-deficient rats at the same rate as retinol. It also stimulated the uptake of [14C]mannose from GDP-[14C]mannose into total chloroform-methanol extractable lipid. This reaction occurred in the presence of ATP, Mn2+, detergent (Zonyl A), and a membrane-rich enzyme preparation from the livers of vitamin A-deficient rats, provided that a lipid extract of the membrane preparation of alpha-L-lecithin was also added. Total chloroform-methanol-extractable, labeled mannolipid was separated into two principal labeled mannolipids by thin-layer or column chromatography or by differential solvent extraction. The properties of these mannolipids identified them as glycophospholipids: one was identical with authentic synthetic dolichyl mannosyl phosphate, and the other was concluded to be mannosyl retinyl phosphate because of its incorporation of radioactivity from [3H]retinyl phosphate, its rapid hydrolysis by dilute acid, and the formation of substance that cochromatographed with retinol upon its acid hydrolysis. The presence of ATP or GTP was essential for the stimulation of mannolipid synthesis, probably because of their protective action on the substrates against phosphatases present in the crude enzyme fraction. A pH of 6.0-6.2 favored the formation of dolichyl mannosyl phosphate; a higher pH (6.7-7.0) that of mannosyl retinyl phosphate.     

A single enzyme catalyzes the synthesis of the mannosylphosphoryl derivative of dolichol and retinol in rat liver and Chinese hamster ovary cells

It is well established that mannosylphosphoryldolichol participates in the synthesis of N-linked glycoproteins by donating mannosyl residues to oligosaccharide-lipid intermediates. It has been suggested that mannosylphosphorylretinol also is involved in glycoprotein biosynthesis. We conclude that one synthase catalyzes the synthesis of both mannosylphosphoryldolichol and mannosylphosphorylretinol in rat liver tissue and Chinese hamster ovary cells, based on the following results. 1) The enzyme in rat liver microsomes that synthesizes mannosylphosphoryldolichol and mannosylphosphorylretinol is inactivated at the same rate at 55 degrees C. 2) In membranes of both rat liver and Chinese hamster ovary cells, exogenous dolichyl phosphate and retinyl phosphate compete with each other for mannosyl-lipid synthesis. However, in both systems adding exogenous retinyl phosphate has no effect on the synthesis of mannosylphosphoryldolichol from endogenous dolichyl phosphate in the membranes. 3) Membranes prepared from a mutant of Chinese hamster ovary cells which is devoid of mannosylphosphoryldolichol synthase lack the ability to synthesize mannosylphosphorylretinol.     

A mutant of Chinese hamster ovary cells with a reduction in levels of dolichyl phosphate available for glycosylation

F2A8, a glycosylation mutant of Chinese hamster ovary cells, was isolated without prior enrichment or selective procedures by screening colonies for reduced [3H]mannose incorporation into macromolecules. F2A8 cells incubated with [3H]mannose synthesized 70% the amount of labeled GDP-mannose found in parental cells, and the same oligosaccharides attached to lipid and protein as did parental cells, but in reduced amounts. Incorporation of radioactivity from labeled mannose into saccharide-lipids and into total glycopeptides of F2A8 was reduced 7-fold compared to parental cells. In addition, glycosylation of the vesicular stomatitis virus glycoprotein was reduced in F2A8 cells as assessed by a mobility intermediate between normally glycosylated and unglycosylated protein during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In vitro assays using membrane preparations showed that F2A8 had parental levels of glucosylphosphoryldolichol synthase and of UDP-GlcNAc:dolichyl phosphate:GlcNAc-phosphotransferase when the enzymatic determinations were done in the presence of exogenous dolichyl phosphate. However, 5-fold less glucosylphosphoryldolichol synthase activity was detected in membranes of F2A8 compared to membranes of parental cells in assays relying on endogenous lipid substrate. F2A8 appears to have reduced amounts of dolichyl phosphate available for its glycosylation reactions.     

Interactions between retinyl phosphate and bivalent cations.

In the presence of Mn(II) ions, the u.v. absorption spectrum of retinyl phosphate (Ret-P) solubilized in Triton X-100 micelles, phosphatidylcholine liposomes or rat liver microsomes exhibited a shift from the maximum of 330 nm to 287 nm. The effect of Mn(II) was reversed by adding EDTA or phosphate buffer. The same spectral change was found in the presence of poly-L-lysine in place of Mn(II) ions. The e.s.r. spectrum of Mn(II) in the presence or in the absence of Ret-P clearly showed that approx. 75% of the initial concentration of Mn(II) ions is bound to Ret-P when the molar ratio of Ret-P to Mn(II) ions is 4:1; no such binding occurred in the presence of retinol or retinoic acid. The appearance of two isosbestic points at 303 and 368 nm, in the presence of Mn(II) ions, suggests the existence of an equilibrium between an Mn(II)-bound monomer and an Mn(II)-bound dimer of Ret-P in Triton X-100 micelles. The same effect on the u.v.-absorption spectrum of Ret-P was also induced by Co(II), Cr(II), Zn(II) and Fe(II), but not by Mg2+ or Cu(II). The formation of the 'metachromatic complex' between Ret-P and Mn(II) or Co(II) inhibited the synthesis of retinyl phosphate mannose (Ret-P-Man) from exogenous and endogenous Ret-P and guanosine diphosphate [14C]mannose when bovine serum albumin was added after the metal ion. However, the order of addition did not influence Ret-P-Man synthesis in incubations containing MgCl2, which does not form the metachromatic complex with Ret-P. These results suggest that the bioavailability of proteins, polyamines and metal ions may control the extent to which Ret-P can be mannosylated in the intact membrane.     

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.     

Formation of alpha-1,2- and alpha-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-alpha-D-mannose, p-nitrophenyl-alpha-D-mannose, and free mannose with rat liver microsomal membranes. The products formed during dolichyl mannosyl phosphate incubation with methyl-alpha-D-mannose or with mannose were alpha-linked. The disaccharides formed by incubation of dolichyl mannosyl phosphate or GDPmannose with mannose were identified by paper chromatography and electrophoresis as mannose-alpha-1,2-mannose and mannose-alpha-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-alpha-1,3-mannose was severely inhibited by Triton X-100.     

Enzymatic dephosphorylation of endogenous and exogenous dolichyl monophosphate by calf brain membranes

Calf brain membranes have been shown to enzymatically dephosphorylate endogenous and partially purified, exogenous dolichyl [³²P]monophosphate. The properties and specificity of the dolichyl monophosphatase activity have been studied by following the release of [³²P]phosphate from exogenous dolichyl [³²P]monophosphate added in a dispersion with Triton X-100. The calf brain phosphatase (1) is inhibited by Mn²⁺, Mg²⁺, Ca²⁺, fluoride, and phosphate; (2) exhibits a neutral pH optimum; and (3) has an apparent K_m of 200 μm for dolichyl monophosphate. Dolichyl monophosphatase activity can be distinguished from phosphatidate phosphatase on the basis of their responses to fluoride and phosphate. Based on differential thermolability and the effects of divalent cations and EDTA, the calf brain dolichyl monophosphatase can also be discriminated from the general phosphatase activity assayed with p-nitrophenyl phosphate. Dolichyl monophosphatase activity can be solubilized by treating microsomes with Triton X-100. The enzymatic dephosphorylation of exogenous dolichyl [³²P]monophosphate catalyzed by particulate and detergent-solubilized preparations is negligibly affected by equimolar concentrations of ATP and an assortment of phosphomonoesters, including phosphatidic acid and hexadecyl phosphate. A reduction of approximately 40% in dolichyl monophosphatase activity is observed in the presence of equimolar amounts of retinyl monophosphate. Overall, these results represent good evidence for the presence of a neutral polyisoprenyl monophosphatase in central nervous tissue.     

Characterization of three kinetically distinct forms of glutamate decarboxylase from pig brain.

Hamster liver microsomal membranes catalyse the synthesis of retinyl phosphate mannose (Ret-P-Man) from GDP-mannose and exogenous retinyl phosphate (Ret-P). We have previously shown that maximal Ret-P-Man synthesis occurs in vitro at 20-30 min, followed by a subsequent loss of mannose from Ret-P-Man, suggestive of an intermediary function of Ret-P-Man and/or Ret-P-Man breakdown [Shidoji, Silverman-Jones & De Luca (1982) Biochem. J. 208, 865-868; Creek, Morre, Silverman-Jones, Shidoji & De Luca (1983) Biochem. J. 210, 541-547). To monitor Ret-P-Man synthesis and breakdown carefully, we developed a chromatographic system in which mannose, Ret-P-Man, mannose phosphate and GDP-mannose are separated in a single analysis on a Mono Q column eluted with a gradient of NaCl. Using this chromatographic system, we have determined that 80-90% of the Ret-P-Man made in vitro by hamster liver membranes in 30 min is recovered with the membranes upon centrifugation. Subsequent incubation of Ret-P-Man-loaded membranes at 37 degrees C results in a non-enzymic breakdown of Ret-P-Man to beta-mannopyranosyl phosphate and anhydroretinol. However, incubation of the Ret-P-Man-loaded hamster liver membranes with GDP, but not GMP, ADP, CDP or UDP, results in a loss of mannose from Ret-P-Man and the formation of GDP-mannose and Ret-P. These results demonstrate that Ret-P-Man synthesized in vitro is subject to non-enzymic breakdown to beta-mannopyranosyl phosphate and anhydroretinol and that the GDP-mannose:retinyl phosphate mannosyltransferase reaction is reversible.     

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.     

On the feasibility of electron transfer to singlet oxygen from mitochondrial components

The incorporation of [¹⁴C]mannose from GDP-[¹⁴C]mannose into dolichyl mannosyl phosphate in rat liver microsomes showed a biphasic time-course; an initial rapid incorporation of mannose which ceased within 2 min and a much slower incorporation which continued for 30 min. In the presence of 0.18 mM (250 μg/ml) bacitracin, the rapid incorporation proceeded normally whereas the slow incorporation was inhibited by about 70%. Upon addition of dolichyl pyrophosphate, the microsomes catalyzed the dephosphorylation of the added compound which was also inhibited by bacitracin. The results, coupled with several other observations, suggest that the rapid reaction represents the transfer of mannose to endogenous dolichyl phosphate whereas the bacitracin-sensitive, slow reaction represents a more complex process in which the enzymatic dephosphorylation of dolichyl pyrophosphate is involved as a rate-limiting step.