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.     

Mannosyltransferase activity in calf pancreas microsomes. Formation of 14C-labeled lipid-linked oligosaccharides from GDP-D-[14C]mannose and pancreatic dolichyl beta-D-[14C]mannopyranosyl phosphate.

Calf pancreas microsomes incorporated radioactive D-mannose from GDP-D-[14C]mannose into lipid-bound oligosaccharides extracted with chloroform/methanol/water (10/10/2.5, v/v). Several products, which probably differed in the size of the oligosaccharide moiety, were labeled. These could be partially resolved by thin layer chromatography and DEAE-cellulose chromatography. The labeled lipid-bound oligosaccharides were retained on DEAE-cellulose more strongly than synthetic dolichyl alpha-D-[14C]mannopyranosyl phosphate. They were stable to mild alkali, but labile to acid and hot alkali. Acid treatment yielded a neutral 14C-labeled oligosaccharide fraction which was estimated by gel filtration to have a minimum of 8 monosaccharide residues. Hot alkali treatment yielded a mixture of neutral and acidic 14C-labeled oligosaccharides which could be transformed into neutral products by alkaline phosphatase. The D-[14C]mannose residues were alpha-linked at the nonreducing terminus of the oligosaccharides since they could be removed completely with alpha-mannosidase. Most of the D-[14C]mannose-labeled oligosaccharides were retained on concanavalin A Sepharose and eluted with methyl alpha-D-mannopyranoside. Pancreatic dolichyl beta-D-[14C]mannopyranosyl phosphate incubated with calf pancreas microsomes in the presence of sodium taurocholate was efficiently utilized as donor of alpha-D-mannosyl residues in lipid-bound oligosaccharides. The products formed from dolichyl beta-D-[14C]mannopyranosyl phosphate were identical with those formed from GDP-D-[14C]mannose, and evidence was obtained to show that the dolichyl beta-D-[14C]mannopyranosyl phosphate was serving as donor without prior conversion to GDP-D-[14C]mannose. Transfer of mannose from dolichyl beta-D-[14C]mannopyranosyl phosphate to lipid-bound oligosaccharides took place at a pH optimum of 7.3, whereas transfer to the precipitate containing glycoproteins was greatest at pH 6.0 in Tris/maleate buffer. The addition of divalent cation was not required, but low concentrations of EDTA were extremely inhibitory. The carbohydrate composition of the lipid-bound oligosaccharides of microsomal membranes was investigated by gas-liquid chromatography and by reduction with sodium borotritide. A heterogeneous mixture of oligosaccharides containing N-acetyl-D-glucosamine, D-mannose, and D-glucose varying in proportions from approximately 1/2.5/0.5 to 1/5/1.5 was obtained with glucosamine at the reducing end. Acid treatment of the lipid-bound oligosaccharide fraction yielded dolichyl pyrophosphate, suggesting that at least some of the oligosaccharides were linked to dolichol through a pyrophosphate group.     

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.     

Biosynthesis of lipid-linked oligosaccharides in embryonic liver. Formation of dolichyl pyrophosphate N-acetylglucosaminyl intermediates

Liver microsomes from pig embryos synthesized dolichyl pyrophosphate N-acetylglucosamine and converted it to dolichyl pyrophosphate N,N'-diacetylchitobiose. N-acetylglucosaminyl transferase activity towards dolichol was about 2-fold greater in microsomes from embryonic liver than in microsomes from adult liver. A maximum level of conversion of dolichyl pyrophosphate N-acetylglucosamine to dolichyl pyrophosphate N,N'-diacetylchitobiose was achieved at 5 mM concentration of unlabelled UDP-N-acetylglucosamine, while this conversion was negligible at lower UDP-N-acetylglucosamine concentrations (0.1 and 0.5 mM). The level of dolichyl phosphate, assessed by the level of dolichyl pyrophosphate N-acetylglucosamine synthesis was 2-fold higher in microsomes from embryonic liver than that in microsomes from adult liver. Tunicamycin (1 microgram/ml) inhibited completely the formation of dolichyl pyrophosphate N-acetyl-glucosamine in embryonic liver microsomes, while the inhibitory effect of UMP (1 mM) was about 70%.     

Biosynthesis of P1-di-N-acetyl-alpha-chitobiosyl P2-dolichyl pyrophosphate in calf pancreas microsomes

Calf pancreas microsomes incubated with UDP-N-acetyl-D-[14C] glucosamine in the presence of Mn2+ incorporated radioactivity into P1-2-acetamido-2-deoxy-D-glucopyranosyl P2-dolichyl pyrophosphate and P1-di-N-acetyl-alpha-chitobiosyl P2-dolichyl pyrophosphate. The formation of both glycolipids was enhanced to the same extent by exogenous dolichyl phosphate. Labeled P1-di-N-acetyl-alpha-chitobiosyl P2-dolichyl pyrophosphate was formed from synthetic P1-2-acetamido-2-deoxy-alpha-D-glucopyranosyl P2-dolichyl pyrophosphate and from prelabeled pancreatic P1-2-acetamido-2-deoxy-alpha-D-glucopyranosyl P2-dolichyl pyrophosphate without the addition of divalent cation. Upon thin layer chromatography, it had the same mobility as synthetic P1-di-N-acetyl-alpha-chitobiosyl P2-dolichyl pyrophosphate recently synthesized by Warren et al. (Warren, C. D., Herscovics, A., and Jeanloz, R. W. (1977) Carbohydr. Res., in press), but was different from the synthetic compound prepared by Wedgwood et al. (Wedgwood, J. F., Warren, C. D., Jeanloz, R. W., and Strominger, J. L. (1974) Proc. Natl. Acad. Sci. U. S. A. 71, 5022-5026).     

Biosynthesis of dolichyl pyrophosphate N-acetylglucosaminyl intermediates in liver microsomes from hibernating ground squirrels (Citellus citellus L.)

Dolichyl pyrophosphate N-acetyl[14C]glucosamine was synthesized after incubation of liver microsomes from hibernating ground squirrels with UDP-N-acetyl[14C )glucosamine. The radioactivity of glycolipid formed by liver microsomes from hibernating ground squirrels was about 2-fold greater than by liver microsomes from active animals. Addition of exogenous dolichyl phosphate to the incubation mixture increased the formation of dolichyl pyrophosphate N-acetyl[14C]glucosamine by microsomes from both active and hibernating ground squirrels about 6 times. Liver microsomes from hibernating ground squirrels converted dolichyl pyrophosphate N-acetyl[14C]glucosamine into dolichyl pyrophosphate N,N'-diacetyl[14C]chitobiose in the presence of unlabelled UDP-N-acetylglucosamine. This conversion was maximal at 1.0 M concentration of unlabelled UDP-N-acetylglucosamine. The level of dolichyl phosphate assessed by the level of dolichyl pyrophosphate N-acetylglucosamine formation was nearly 2 times greater in liver microsomes from hibernating ground squirrels than from active animals.     

Synthesis of an unnatural N-glycan-linked dolichyl pyrophosphate precursor

An unnatural alpha-D-mannopyranose-linked chitobiosyl dolichyl pyrophosphate, a stereoisomer of the N-glycan biosynthesis intermediate, was synthesized. The protected trisaccharide, alpha-D-Man-(1-->4)-beta-D-GlcNAc-(1-->4)-D-GlcNAc, carrying a 4-methylbenzoyl group was prepared for the convenience of a TLC analysis. 1-O-Phosphorylation, condensation with dolichyl phosphate, and subsequent deprotection afforded the title compound.     

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.     

Variable product specificity of solanesyl pyrophosphate synthetase

The distribution of polyprenyl pyrophosphates synthesized by the action of solanesyl pyrophosphate synthetase from Micrococcus luteus is dramatically changed depending on the Mg⁺⁺ concentration. When the metal ion concentration is higher than 5 mM, octaprenyl and solanesyl (nonaprenyl) pyrophosphate are synthesized predominantly. On the other hand, when the metal ion level is lower than 0.5 mM, a variety of polyprenyl pyrophosphates ranging in carbon chain length from C₁₅ to C₄₀ are formed. Heptaprenyl pyrophosphate is the longest of the products formed at 0.1 mM of Mg⁺⁺.     

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.     

Enzymatic activities in cultured human lymphocytes that dephosphorylate dolichyl pyrophosphate and dolichyl phosphate

Enzymatic activities which dephosphorylate dolichyl phosphate (Dol-P) and dolichyl pyrophosphate (Dol-P-P) have been observed in membranes from cultured human lymphocytes. Neither activity requires divalent metals. Dol-P phosphatase is inhibited by inorganic phosphate but not by other phosphate-containing compounds. Dol-P-P phosphatase is inhibited by bacitracin but not by phosphate-containing compounds including the methylene analogue of pyrophosphate. These reactions are similar to those previously found in the cycle of bacterial wall peptidoglycan biosynthesis. A chemical synthesis of [32P]Dol-P and [32P]Dol-P-P is reported.     

Biosynthesis of dolichyl phosphate: characterization and site of synthesis in algae

This is the first report not only on the presence of polyprenyl phosphates and their site of synthesis in algae, but also on the formation of their sugar derivatives in this system.

A glucose acceptor lipid was isolated from the nonphotosynthetic alga Prototheca zopfii. The lipid was acidic and resistant to mild acid and alkaline treatments. The glucosylated lipid was labile to mild acid hydrolysis and resistant to phenol treatment and catalytic hydrogenation, as dolichyl phosphate glucose is. These results are consistent with the properties of an α-saturated polyprenyl phosphate.

The polyprenylic nature of the lipid was confirmed by biosynthesis from radioactive mevalonate. The [¹⁴C]lipid had the same chromatographic properties as dolichyl phosphate in DEAE-cellulose and Sephadex LH-20. Strong alkaline treatment and enzymic hydrolysis liberated free alcohols with chain lengths ranging from C₉₀ to C₁₀₅, C₉₅ and C₁₀₀ being the most abundant molecular forms. The glucose acceptor activity of the biosynthesized polyprenyl phosphate was confirmed.

The ability of different subcellular fractions to synthesize dolichyl phosphate was studied. Mitochondria and the Golgi apparatus were the sites of dolichyl phosphate synthesis from mevalonate.

     

Characterization of undecaprenyl pyrophosphate synthetase from Lactobacillus plantarum

A soluble long-chain polyprenyl pyrophosphate synthetase has been isolated from Lactobacillus plantarum and partially purified by DEAE-cellulose chromotography in 1% Triton X-100. This enzyme catalyzes the synthesis of polyprenyl pyrophosphate from farnesyl pyrophosphate and Δ³-isopentenyl pyrophosphate. The enzyme displays a requirement for farnesyl pyrophosphate and Triton X-series detergents. Treatment of polyprenyl pyrophosphate with C₅₅-isoprenyl pyrophosphate phosphatase (Micrococcus lysodeikticus) yielded polyprenyl monophosphate. Subsequent treatment of this product with a crude phosphatase from baker's yeast resulted in the formation of free polyprenol, which was characterized by thin layer chromatography and exhibited R_fs which corresponded to those of authentic undecaprenol isolated from Lactobacillus plantarum. Reverse phase cochromatography of the enzymically produced polyprenol and authentic undecaprenol indicated that the major enzymic products were undecaprenol and probably a longer chain polyprenol.     

New developments in the synthesis of phosphopolyprenols and their glycosyl esters.

Efficient methods were developed in our group in recent years for chemical synthesis of polyprenyl phosphates, polyprenyl monophosphate sugars, and polyprenyl diphosphate sugars, which were known to serve as important intermediates in biosynthesis of complex carbohydrates. A simple procedure was developed involving the phosphorylation of aliphatic alcohols with tetra-n-butylammonium dihydrogen phosphate and trichloroacetonitrile. Monophosphates of various natural and modified dolichols and polyprenols, as well as the derivatives of retinol, cholesterol, and nonacosanol, were prepared in high yields. First syntheses of dolichyl thiophosphate and dolichyl hydrogen phosphonate were developed, and these derivatives were of interest as analogs of dolichyl phosphate. Polyprenyl monophosphate sugars, including derivatives of alpha- and beta-anomers of D-glucopyranose, D-galactopyranose, D-mannopyranose, and 2-acetamido-2-deoxy-D-glucopyranose, were obtained smoothly from moraprenyl trichloroacetimidate and acylated glycosyl phosphates after deprotection. A method for the synthesis of polyprenyl diphosphate sugars from polyprenyl phosphoroimidazolidate and unprotected glycosyl phosphates was shown to be applicable for a wide range of the monosaccharide derivatives including hexoses, deoxyhexoses, 2-acetamido-2-deoxyhexoses, and uronic acids. A series of the oligosaccharide derivatives was also prepared by this method.     

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.     

Dehydrodolichyl diphosphate synthetase from rat seminiferous tubules

Homogenates of seminiferous tubules from rat testes catalyzed the incorporation of label from [14C]isopentenyl diphosphate into a variety of polyprenyl products. Long chain polyprenyl mono- and diphosphates were formed as major products when undesirable side reactions were minimized. The long chain polyprenyl diphosphate synthetase was measured as a sum of the mono- and diphosphate derivatives formed and was dependent on the addition of t,t-farnesyl diphosphate, isopentenyl diphosphate, and divalent cation. The highest activity was associated with the membranous fractions, whereas activity was negligible in the cytosolic fraction. The products of this prenyl transferase were labile to acid and yielded petroleum ether soluble products which indicated that the alpha-isoprene unit was unsaturated. Hydrolysis of either the polyprenyl mono-or diphosphates with a testicular phosphatase in the absence of NaF yielded C75, C80, C85, and C90 polyprenols. The chain lengths of the products of the synthetase suggest that this enzyme is responsible for the de novo biosynthesis of dehydrodolichyl diphosphates which are precursors of the dolichyl derivatives found in testes.     

Purification and properties of a phosphohydrolase from Enterobacter aerogenes.

A phosphohydrolase from Enterobacter aerogenes which hydrolyzes phosphate mono- and diesters has been purified approximately 50-fold to apparent homoeneity and crystallized. The enzyme is produced when the bacteria utilize phosphate diesters as sole phosphorus source. From sedimentation equilibrium experiments the molecular weight of the native enzyme is 173,000; from sodium dodecyl sulfate polyacrylamide gel electrophoresis the subunit molecular weight is 29,000, indicating that the enzyme is hexameric. The hydrolytic activity of the enzyme using both mono- and diesters is maximal at pH 5; THE Km of the enzyme for bis-p-nitrophenyl phosphate is constant from pH 5 to 8.5 whereas that for p-nitrophenyl phosphate increases about 40-fold as the pH increases over the same range. The phosphodiesterase activity is not inhibited by chelating agents but is inhibited by several divalent metal ions. 31-P NMR spectroscopy was used to identify the hydrolysis products of glycoside cyclic phosphates. The enzyme-catalyzed hydrolysis of methyl beta-D-ribofuranoside cyclic 3:5-phosphate yields exclusively the 5-phosphate whereas that of adenosine 3:5-monophosphate yields a 4:1 mixture of 3- and 5- AMP.     

Covalent binding of dolichyl phosphate to proteins in rat liver

Rats were injected via the portal vein with (RS)-[5-3H]-mevalonolactone and the lipids were extracted. From fractions of liver homogenate, all labeled dolichol, cholesterol and ubiquinone could be extracted, but about 40% of microsomal and lysosomal dolichyl phosphate was only released after alkaline hydrolysis. Only a small amount of the non-extractable radioactivity was found to be associated with alpha-unsaturated polyprenyl phosphate. There was no difference in the polyisoprenoid pattern when the two pools of dolichyl phosphate were compared. On the other hand, the specific activity of the bound lipid was only half that of the extractable form. After phenyl-Sepharose chromatography, a peak of protein was isolated exhibiting a 25-fold enrichment in bound radioactive dolichyl phosphate. Treatment with a non-specific protease, followed by chromatography, gave polypeptide fragments associated with bound lipids. On SDS/PAGE a major protein band at 23 kDa and some minor bands with higher molecular masses were found to be associated with this lipid. The results indicate the presence of covalently bound dolichyl phosphate in rat liver.     

CpsE from type 2 Streptococcus pneumoniae catalyzes the reversible addition of glucose-1-phosphate to a polyprenyl phosphate acceptor, initiating type 2 capsule repeat unit formation

The majority of the 90 capsule types made by the gram-positive pathogen Streptococcus pneumoniae are assembled by a block-type mechanism similar to that utilized by the Wzy-dependent O antigens and capsules of gram-negative bacteria. In this mechanism, initiation of repeat unit formation occurs by the transfer of a sugar to a lipid acceptor. In S. pneumoniae, this step is catalyzed by CpsE, a protein conserved among the majority of capsule types. Membranes from S. pneumoniae type 2 strain D39 and Escherichia coli containing recombinant Cps2E catalyzed incorporation of [14C]Glc from UDP-[14C]Glc into a lipid fraction in a Cps2E-dependent manner. The Cps2E-dependent glycolipid product from both membranes was sensitive to mild acid hydrolysis, suggesting that Cps2E was catalyzing the formation of a polyprenyl pyrophosphate Glc. Addition of exogenous polyprenyl phosphates ranging in size from 35 to 105 carbons to D39 and E. coli membranes stimulated Cps2E activity. The stimulation was due, in part, to utilization of the exogenous polyprenyl phosphates as an acceptor. The glycolipid product synthesized in the absence of exogenous polyprenyl phosphates comigrated with a 60-carbon polyprenyl pyrophosphate Glc. When 10 or 100 microM UMP was added to reaction mixtures containing D39 membranes, Cps2E activity was inhibited 40% and 80%, respectively. UMP, which acted as a competitive inhibitor of UDP-Glc, also stimulated Cps2E to catalyze the reverse reaction, with synthesis of UDP-Glc from the polyprenyl pyrophosphate Glc. These data indicated that Cps2E was catalyzing the addition of Glc-1-P to a polyprenyl phosphate acceptor, likely undecaprenyl phosphate.     

Studies on the regulation of glycoprotein biosynthesis. An investigation of the rate-limiting steps of dolichyl phosphate biosynthesis.

The possible role of HMG-CoA (3-hydroxy-3-methylglutaryl coenzyme A) reductase (the rate-controlling enzyme of cholesterol biosynthesis) in regulating the rate of dolichyl phosphate biosynthesis in rat liver was investigated. Rats were either fasted 48 h or fed diets supplemented with the drug cholestyramine. The activity of HMG-CoA reductase was 5000-fold greater in liver from cholestyramine-fed rats as compared to fasted rats. The activity of dolichyl phosphate synthetase, the prenyl transferase responsible for the biosynthesis of dolichyl phosphate from farnesyl pyrophosphate and isopentenyl pyrophosphate, was similar in both nutritional conditions and was markedly less active than HMG-CoA reductase even in the fasted state. Acetate incorporation into cholesterol was 2200-fold greater in liver slices from cholestyramine-fed rats as compared to fasted rats. By contrast, acetate incorporation into dolichyl phosphate was only 6-fold higher. Further studies suggested that the levels of farnesyl pyrophosphate and isopentenyl pyrophosphate are several hundred-fold greater in liver from cholestyramine-treated rats. From these results, it is concluded that the rate of dolichyl phosphate biosynthesis in rat liver is not regulated by the activity of HMG-CoA reductase but is probably regulated at the level of dolichyl phosphate synthetase.