Cell-cycle dependence of dolichyl phosphate biosynthesis

The cell-cycle dependence of dolichyl phosphate biosynthesis has been investigated in mouse L-1210 cells fractionated by centrifugal elutriation. Dolichyl phosphate levels increased linearly through the cell cycle, reaching a value in late S phase twice that of early G1. The cell-cycle dependences of four dolichyl phosphate metabolizing enzymes have been measured: cis-prenyltransferase, CTP-dependent dolichol kinase, dolichyl phosphatase, and dolichyl pyrophosphatase. The kinase, the cis-prenyltransferase, and the pyrophosphatase showed cell-cycle variations, increasing through G1 to a maximum in S phase while the monophosphatase activity was cell-cycle independent. The rate of accumulation of dolichyl phosphate was not affected by growing the cells in mevalonolactone-supplemented media. The evidence presented is consistent with models in which either the cis-prenyltransferase or the kinase/phosphatase couple (or both) regulates the levels of dolichyl phosphate in the cell.     

The mechanism and regulation of dolichyl phosphate biosynthesis in rat liver

Rat liver slices were pulse labeled for 6 min with [3H]mevalonolactone and then chased for 90 min with unlabeled mevalonolactone in order to study the mechanism of dolichyl phosphate biosynthesis. The cholesterol pathway was also monitored and served to verify the pulse-chase. Under conditions in which radioactivity in the methyl sterol fraction chased to cholesterol, radioactivity in alpha-unsaturated polyprenyl (pyro)-phosphate chased almost exclusively into dolichyl (pyro)phosphate. Lesser amounts of radioactivity appeared in alpha-unsaturated polyprenol and dolichol, and neither exhibited significant decline after 90 min of incubation. The relative rates of cholesterol versus dolichyl phosphate biosynthesis were studied in rat liver under four different nutritional conditions using labeled acetate, while the absolute rates of cholesterol synthesis were determined using 3H2O. From these determinations, the absolute rates of dolichyl phosphate synthesis were calculated. The absolute rates of cholesterol synthesis were found to vary 42-fold while the absolute rates of dolichyl phosphate synthesis were unchanged. To determine the basis for this effect, the rates of synthesis of cholesterol and dolichyl phosphate were quantitated as a function of [3H]mevalonolactone concentration. Plots of nanomoles incorporated into the two lipids were nearly parallel, yielding Km values on the order of 1 mM. In addition, increasing concentrations of mevinolin yielded parallel inhibition of incorporation of [3H]acetate into cholesterol and dolichyl phosphate. The specific activity of squalene synthase in liver microsomes from rats having the highest rate of cholesterol synthesis was only 2-fold greater than in microsomes from rats having the lowest rate. Taken together, the results suggest that the maintenance of constant dolichyl phosphate synthesis under conditions of enhanced cholesterogenesis is not due to saturation of the dolichyl phosphate pathway by either farnesyl pyrophosphate or isopentenyl pyrophosphate but coordinate regulation of hydroxymethylglutaryl-CoA reductase and a reaction on the pathway from farnesyl pyrophosphate to cholesterol.     

Identification of rate-limiting steps in yeast heme biosynthesis

The heme biosynthesis pathway in the yeast Saccharomyces cerevisiae is a highly regulated system, but the mechanisms accounting for this regulation remain unknown. In an attempt to identify rate-limiting steps in heme synthesis, which may constitute potential regulatory points, we constructed yeast strains overproducing two enzymes of the pathway: the porphobilinogen synthase (PBG-S) and deaminase (PBG-D). Biochemical analysis of the enzyme-overproducing strains revealed intracellular porphobilinogen and porphyrin accumulation. These results indicate that both enzymes play a rate-limiting role in yeast heme biosynthesis.     

In vivo biosynthesis of the saturated isoprene unit of dolichyl phosphate

Reduction of the e-isoprene unit of polyprenols to form dolichols was studied in vivo using³H-polyprenol derivatives as substrates and liposomes as carriers. Liposomes containing labeled polyprenol, polyprenyl phosphate, or polyprenyl pyrophosphate were injected through the portal vein into the livers of rats under anesthesia. Uptake and conversion of the labeled compounds to dolichol derivatives was studied at different intervals. The greatest conversion to dolichol derivatives was found with polyprenyl pyrophosphate and polyprenyl monophosphate, with 31% and 8% of the absorbed dose converted respectively. Less than 0.2% of the absorbed polyprenol was converted to dolichol derivatives. These results suggest that the substrate for the -isoprene reductase involved in dolichol biosynthesis is either polyprenyl monophosphate or polyprenyl pyrophosphate, or both.     

Characterization of the Saccharomyces cerevisiae cis-prenyltransferase required for dolichyl phosphate biosynthesis

The prenyltransferase involved in the biosynthesis of dolichyl phosphate has been characterized in Saccharomyces cerevisiae. Although the enzyme is predominantly membrane-bound, a significant percentage was found in the soluble fraction. The prenyltransferase preferentially utilizes farnesyl pyrophosphate as the allylic substrate and isopentenyl pyrophosphate as cosubstrate with half-maximal velocities obtained at 25 and 6.7 microM, respectively. The enzymatic activity is sensitive to sulfhydryl reagents and is inhibited by all detergents tested, except 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate at concentrations less than 5 mM. The product of the reaction has been characterized as an alpha-unsaturated polyprenyl pyrophosphate, containing 12-15 isoprene units, approximately two isoprene units shorter than the endogenous yeast dolichyl phosphate. The stereochemistry of addition of isoprene units by the prenyltransferase was shown to be cis by a comparison of the HPLC retention time for a pentadecaprenyl phosphate derived from the in vitro reaction product with that for an authentic mixture of alpha-cis- and alpha-trans-pentadecaprenyl phosphates.     

Inhibition of dolichyl phosphate biosynthesis by compactin in cultured rat hepatocytes

Isolated rat hepatocytes were cultured in monolayer for about 24 h. During this period the cells exhibited constant protein and lipid synthesis. When the culture medium contained compactin, a competitive inhibitor of the 3-hydroxyl-3-methylglutary-coenzyme-A reductase, dolichyl-P synthesis was inhibited by 91% at the end of the incubation, as estimated by the incorporation of [3H]acetate and by 77% as estimated by the incorporation of 32Pi. These results indicate that in primary cultures of rat hepatocytes dolichyl monophosphate is mainly synthesized through a de novo process, while phosphorylation through the CTP-mediated kinase is of limited functional importance.     

Transient methylation of dolichyl oligosaccharides is an obligatory step in halobacterial sulfated glycoprotein biosynthesis

Biosynthesis of sulfated saccharides that are linked to asparagine residues in the cell surface glycoprotein of Halobacterium halobium via a glucose residue involves sulfated dolichyl-monophosphoryl oligosaccharide intermediates (Lechner, J., Wieland, F., and Sumper, M. (1985) J. Biol. Chem. 260, 860-866). During isolation and characterization of these lipid oligosaccharides we detected a group of related compounds containing additional unidentified sugar residues. Here we report that: 1) the unknown sugar residues were 3-O-methylglucose, linked peripherally to the lipid-saccharide intermediates; 2) the 3-O-methylglucose residues in the oligosaccharides occur only at the lipid-linked level but are absent at the protein-linked level; 3) cell surface glycoprotein biosynthesis in Halobacteria in vivo is drastically depressed when S-adenosylmethionine-dependent methylation is inhibited, indicating that methylation is an obligatory step during glycoprotein synthesis. We propose a mechanism for the transport of lipid oligosaccharides through the cell membrane, involving an intermediate stage in which the saccharide moieties are transiently modified with 3-O-methylglucose.     

Studies on the biosynthesis of dolichyl phosphate: Evidence for the in vitro formation of 2,3-dehydrodolichyl phosphate

A particulate enzyme preparation from hen oviduct is shown to carry out the biosynthesis of a long chain polyprenyl phosphate from isopentenyl pyrophosphate and farnesyl pyrophosphate. The compound has the physical and chemical properties of 2,3-dehydrodolichyl phosphate. The enzyme system is inhibited by EDTA and stimulated by Triton X-100 and dithiothreitol. If the product of the reaction is 2,3-dehydrodolichyl phosphate, it may be derived from 2,3-dehydrodolichyl pyrophosphate, a likely intermediate in the biosynthesis of dolichyl phosphate.     

Identification of rate-limiting steps in cephalosporin C biosynthesis in Cephalosporium acremonium: a theoretical analysis

Summary A kinetic model describing the biosynthesis of celphalosporin C in Cephalosporium acremonium has been developed to identify the rate-limiting step(s). Using this model and in-vitro kinetic data of the biosynthetic enzymes, the production kinetics of cephalosporin C were examined theoretically. The predicted time profile of the specific production rate during batch culture is in good agreement with that of experimental results published previously. Sensitivity analysis indicates that -(l--aminoadipyl)-l-cysteinyl-d-valine (ACV) synthetase is the rate-limiting enzyme. Our analysis also predicts that increasing ACV synthetase enhances the production rate initially until expandase/hydroxylase becomes rate-limiting. Furthermore, increasing expandase/hydroxylase reduces the accumulation of penicillin N, and thus, enhances the production of cephalosporin C. Based on our analysis, amplifying both ACV synthetase and expandase/hydroxylase concurrently should enhance the production rate to a great extent.Correspondence to: W. S. Hu     

Uridine and dolichyl diphosphate activated oligosaccharides are intermediates in the biosynthesis of the S-layer glycoprotein of Methanothermus fervidus

The surface of the extremely thermophilic archaebacterium Methanothermus fervidus is covered by glycoprotein subunits. The carbohydrate moiety of the surface glycoprtein accounts for about 17 mol%. It is composed of mannose, 3-O-methylglucose, galactose, N-acetylglucosamine and N-acetylgalactosamine. From cell extracts the corresponding surgar-1-phosphates and nucleotide activated derivatives of Man, Gal, GlcNAc and GalNAc were isolated. Furthermore UDP-and dolichyl activated oligosaccharides were obtained. On the basis of the isolated precursors a pathway for the biosynthesis of the oligosaccharide chains is proposed.Abbreviations DNP-Glu N-2,4-dinitrophenyl-glutamic acid - Dol dolichol - Gal galactose - Gal-1-P galactose-1-phosphate - GalNAc N-acetylgalactosamine - GalNAc-1-P N-acetylgalactosamine-1-phosphate - Glc glucose - GlcNAc N-acetylglucosamine - GlcNAc-1-P N-acetylglucosamine-1-phosphate - Man mannose - Man-1-P mannose-1-phosphate - 3-O-MeGlc 3-O-methylglucose - P phosphate - TCA trichloroacetic acid - TLC thin-layer chromatography - Tris tris(hydroxymethyl)aminomethan     

Studies on the time course and rate-limiting steps in the activation of adenylate cyclase in rat liver by cholera toxin.

Cholera toxin stimulates adenylate cyclase in rat liver after intravenous injection. The stimulation follows a short latent period of 10min, and maximum stimulation was attained at 120min. Half-maximal stimulation was achieved at 35min. In contrast with this lengthy time course in the intact cell, adenylate cyclase in broken-cell preparations of rat liver in vitro were maximally stimulated by cholera toxin (in the presence of NAD+) in 20min with half-maximal stimulation in 8min. Binding of cholera toxin to cell membranes by the B subunits is followed by translocation of the A subunit into the cell or cell membrane, and separation of the A1 polypeptide chain from the A2 chain by disulphide-bond reduction, and finally activation of adenylate cyclase by the A1 chain and NAD+. As the binding of cholera toxin is rapid, two possible rate-limiting steps could be the determinants of the long time course of action. These are translocation of the A1 chain from the outside of the cell membrane to its site of action (this includes the time required for separation from the whole toxin) or the availability of NAD+ for activation. When NAD+ concentrations in rat liver were elevated 4-fold, by the administration of nicotinamide, no change in the rate of activation of adenylate cyclase by cholera toxin was observed. Thus the intracellular concentration of NAD+ is not rate-limiting and the major rate-limiting determinant in intact cells must be between the time of toxin binding to the cell membrane and the appearance of subunit A1 at the enzyme site.     

The ins(ide) and out(side) of dolichyl phosphate biosynthesis and recycling in the endoplasmic reticulum.

The precursor oligosaccharide donor for protein N-glycosylation in eukaryotes, Glc3Man9GlcNAc(2)-P-P-dolichol, is synthesized in two stages on both leaflets of the rough endoplasmic reticulum (ER). There is good evidence that the level of dolichyl monophosphate (Dol-P) is one rate-controlling factor in the first stage of the assembly process. In the current topological model it is proposed that ER proteins (flippases) then mediate the transbilayer movement of Man-P-Dol, Glc-P-Dol, and Man5GlcNAc(2)-P-P-Dol from the cytoplasmic leaflet to the lumenal leaflet. The rate of flipping of the three intermediates could plausibly influence the conversion of Man5GlcNAc(2)-P-P-Dol to Glc3Man(9)GlcNAc(2)-P-P-Dol in the second stage on the lumenal side of the rough ER. This article reviews the current understanding of the enzymes involved in the de novo biosynthesis of Dol-P and other polyisoprenoid glycosyl carrier lipids and speculates about the role of membrane proteins and enzymes that could be involved in the transbilayer movement of the lipid intermediates and the recycling of Dol-P and Dol-P-P discharged during glycosylphosphatidylinositol anchor biosynthesis, N-glycosylation, and O- and C-mannosylation reactions on the lumenal surface of the rough ER.     

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.     

Anomeric configuration of the dolichyl D-mannosyl phosphate formed in calf pancreas microsomes.

Dolichyl D-[14C]mannosyl phosphate formed in calf pancreas microsomes was compared to dolichyl alpha-D-[14C]mannopyranosyl phosphate, a chemical synthesis of which is described. Jack bean alpha-mannosidase, which converted citronellyl alpha-D-mannopyranosyl phosphate, but not its beta anomer, to citronellyl phosphate and D-mannose, was effective in releasing D-[14C]mannose from dolichyl alpha-D-[14C]manopyranosyl phosphate in the presence of detergent. In contrast, alpha-mannosidase did not cause any significant release from the pancreatic dolichyl D-[14C]mannosyl phosphate. Alkali treatment (0.1 M NaOH in propanol at 65 and 90 degrees) degraded both dolichyl D-[14C]mannosyl phosphates with the formation of water-soluble 14C-labeled products. The pattern of 14C-labeled breakdown products formed from the synthetic dolichyl alpha-D-[14C]mannopyranosyl phosphate differed from that obtained from the pancreatic dolichyl D-[14C]mannosyl phosphate. Dolichyl alpha-D-[14C]mannopyranosyl phosphate yielded several 14C-labeled products, including a trace of D-[14C]mannosyl phosphate, and an acidic fraction which appeared to result from degradation of D-[14C]mannose. The pancreatic dolichyl D-[14C]mannosyl phosphate gave various products, depending on the temperature of the reaction: at 90 degrees, 20 to 30% of the radioactivity was found in D-[14C]mannosyl phosphate and the rest in acidic breakdown products; at 65 degrees, about two-thirds of the radioactivity was recovered in a compound which behaved as D-MANNOSE 2-PHOSPHATE, A Product characteristic of a beta-linked D-mannosyl residue. It is concluded that the pancreatic compound is dolichyl beta-D-[14C]mannosyl phosphate.