A lipid-linked oligosaccharide intermediate in glycoprotein synthesis in oviduct. Structural studies on the oligosaccharide chain.

The structure of the oligosaccharide chain of the lipid-linked oligosaccharide that serves as a donor of oligosaccharide chain to proteins of hen oviduct membranes has been investigated. A [Man-14C]glycopeptide fraction was prepared from membrane glycoproteins labeled with GDP-[14C]mannose. Reductive alkaline cleavage of this glycopeptide yielded a reduced oligosaccharide that, by four criteria, was identical with reduced [Man-14C]oligosaccharide prepared from [Man-14C]oligosaccharide-lipid. The structure of the oligosaccharide chain of the [Man-14C]glycopeptide was investigated by cleavage with a specific endo-beta-N-acetylglucosaminidase, followed by treatment of the released oligosaccharide with purified al alpha-and beta-mannosidases. By this procedure it was possible to establish the structure of the cleavage product as (alpha-Man)n-beta-Man-(1 leads to 4)-GlcNAc. Similar studies were performed on the [GlcNAc-14C]oligosaccharide prepared by hydrolysis of [GlcNAc-14C]oligosaccharide-lipid. The results indicate that the structure of the intact oligosaccharide is (alpha-Man)n-beta-Man-(1 leads 4)-beta-GlcNAc-(1 leads to 4)-GlcNAc. These experiments, coupled with earlier enzymatic studies on synthesis of the glycoproteins from the lipid-linked oligosaccharide, provide strong evidence that the structure of the oligosaccharide intermediate and the oligosaccharide chain of the glycoprotein product contain the same core structure found in many secretory glycoproteins.     

The participation of lipid-linked oligosaccharide in synthesis of membrane glycoproteins.

Membrane preparations from hen oviduct catalyze the transfer of mannose from GDP-mannose into three components: mannosyl phosphoryl polyisoprenol, oligosaccharide-lipid, and glycoprotein. Eivence that mannosyl phosphoryl polyisoprenol serves as a mannosyl donor for synthesis of both oligosaccharide-lipid and glycoproteins was previously reported (Waechter, C.J., Lucas, J.J., and Lennarz, W.J. (1973) J. Biol. Chem. 248, 7570-7579). In this study the oligosaccharide-lipid has been isolated, and the oligosaccharide has been partially characterized. Based on paper chromatography the oligosaccharide chain contains 7 to 9 glycose units. The glycose at the reducing terminus is N-acetylglucosamine, whereas mannose is found at the nonreducing end. When UDP-N-acetyl[14C]glucosamine is incubated with oviduct membranes in the absence of GDP-mannose, a 14C-labeled chitobiosyl lipid, but little oligosaccharide-lipid is synthesized. When GDP-mannose is also present in the incubation mixture an oligosaccharide-lipid is formed containing N-acetyl[14C]glucosaminyl residues. This oligosaccharide-lipid is chromatographically identical with the [14C]mannose-containing oligosaccharide-lipid isolated in the earlier study cited above. When the N-acetyl[14C]glucosamine-oligosaccharide released from the oligosaccharide-lipid by mild acid is treated with partially purified alpha-mannosidase the major radioactive product is [14C]chitobiose. Evidence that the [14C]mannose-containing oligosaccharide-lipid serves as an oligosaccharide donor for glycoprotein synthesis was obtained by incubation of partially purified oligosaccharide-lipid with the membranes. The products of this incubation were shown to be glycoproteins on the basis of their sensitivity to pronase, as determined by both gel filtration and paper electrophoresis. Similar experiments, using oligosaccharide-lipid doubly labeled with [14C]mannose and N-acetyl[3H]glucosamine, provided evidence that the oligosaccharide chain of the oligosaccharide-lipid is transferred en bloc to glycoprotein s.     

Sindbis envelope proteins as endogenous acceptors in reactions of guanosine diphosphate-[14C]Mannose with preparations of infected chicken embryo fibroblasts.

Preparations of Sindbis-infected chicken embryo fibroblasts incubated with GDP-[14C]mannose and UDP-N-acetylglucosamine catalyze the glycosylation of endogenous phospholipids and membrane-associated proteins. The proteins are identified as the viral envelope proteins by precipitation with anti-Sindbis antiserum, by comparison with authentic virion glycoproteins on sodium dodecyl sulfate-poly-acrylamide gel electrophoresis, and by comparison of the glycopeptides of the membrane-associated glycoproteins with the glycopeptides from Sindbis virions on gel filtration chromatography. Our results indicate that glycophospholipid participates in the mannosylation of the viral proteins since an inhibitor of oligosaccharide-lipid synthesis also inhibits the labeling of the glycoproteins.     

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.     

Participation of a trisaccharide-lipid in glycosylation of oviduct membrane glycoproteins.

Preincubation of a hen oviduct membrane preparation with UDP-Nactyl[14C]glucosamine and bacitracin, followed by incubation with GDP-mannose, leads to formation of a chloroform/methanol (2/1)-extractable glycolipid. Treatment of the lipid with mild acid results in the release of a trisaccharide shown to have the structure beta-mannosyl-N-acetylglucosamineyl-N-acetylglucosamine. Incubation of purified trisaccharide-lipid with oviduct membranes in the presence of sodium deoxycholate, Mn2+, and GDP-mannose leads to formation of a labeled glycoprotein with an apparent molecular weight of 25,000...     

Biosynthesis of mammary glycoproteins. Partial characterization of the sequence for the assembly of lipid-linked saccharides

Incubation of a membrane preparation from the lactating bovine mammary gland with UDP-[3H]GlcNAc, GDP-[14C]Man, and UDP-[3H]Glc results in the biosynthesis of 15 lipid-linked saccharides that differ from one another by a monosaccharide unit. Pulse and chase kinetics indicate that these glycolipids are related to one another as precursor products for the biosynthesis of asparagine-linked glycoproteins of this tissue. [Man-14C]- and [Man-14C, GlcNAc-3H]saccharides were prepared from corresponding glycolipids by mild acid hydrolysis. Following extensive purification by paper and gel filtration chromatography, structural characterization was conducted on tri-, tetra-, penta-, and undecasaccharides via size determination on calibrated columns of Bio-Gel P-2 and P-4, compositional analysis, exo- and endoglycosidase digestions, methylation, Smith degradation, and acetolysis. These structures were identified as: Man beta 1 leads to 4(3)GlcNAc beta 1 leads to 4(3)Glc-NAc, Man alpha 1 leads to 3Man beta 1 leads to 4(3)GlcNAc beta 1 leads to 4(3)GlcNAc, Man alpha 1 leads to 3(Man alpha 1 leads to 6)Man beta 1 leads to 4(3)Glc NAc beta 1 leads to 4(3)Glc-NAc, and Man alpha 1 leads to 2 Man alpha 1 leads to 2Man alpha 1 leads to 3(Man alpha 1 leads to 2Man alpha 1 leads to 6[Man alpha 1 leads to 2Man alpha 1 leads to 3]Man alpha 1 leads to 6)Man beta 1 leads to 4(3)GlcNAc beta 1 leads to 4(3)GlcNAc.     

alpha-Dihydrodecaprenyl phosphate as a sugar carrier in the membrane of AH 70Btc hepatoma cells

The effect of alpha-dihydrodecaprenyl phosphate, dolichyl phosphate and solanesyl phosphate on the lipid intermediate pathway for protein glycosylation was studied with crude membrane fraction prepared from AH 70Btc hepatoma cells. alpha-Dihydrodecaprenyl phosphate increased the incorporations of [14C]mannose from GDP-[14C]mannose into CHCl3-CH3OH (2:1, v/v) extract, oligosaccharide-lipid and proteins. The above and the other data showed that alpha-dihydrodecaprenyl phosphate may function as a mannose carrier in the lipid intermediate pathway.     

A concanavalin A-resistant Chinese hamster ovary cell line is deficient in the synthesis of [3H]glucosyl oligosaccharide-lipid.

In this report we present an initial determination of the biochemical defect present in a Chinese hamster ovary cell line selected for resistance to concanavalin A. Membranes of this mutant, B211, incorporated at least 10-fold less mannose from GDP-[14C]mannose into oligosaccharide-lipid than membranes of the wild type. In the presence of dolichol phosphate, membranes of the mutant and wild type exhibited similar rates of synthesis of number of early intermediates, namely, mannosylphosphoryldolichol, N-acetylglucosaminyl- and N,N'-diacetylchitobiosylpyrophosphoryldolichol, glucosylphosphoryldolichol, and mannosyloligosaccharide-lipid. The membranes of B211 did not incorporate glucose from UDP-[3H]glucose into oligosaccharide-lipid or protein. Comparison by gel filtration chromatography of oligosaccharides derived from the oligosaccharide-lipids of B211 and wild type cells labeled with [2-3H]mannose revealed that B211 cells incorporated little if any label into an oligosaccharide corresponding to the most excluded oligosaccharide labeled by wild type cells. This concanavalin A-resistant cell line appears to lack the ability to glucosylate oligosaccharide-lipid.     

Cephalosporin-sensitive penicillin-binding proteins of Staphylococcus aureus and Bacillus subtilis active in the conversion of [14C]penicillin G to [14C]phenylacetylglycine.

Breakdown of the covalent complex formed between [14C]penicillin G and higher molecular weight, cephalosporin-sensitive penicillin-binding proteins was studied using mixtures of the purified proteins isolated from membranes of Staphylococcus aureus and Bacillus subtilis. These penicillin-binding proteins were found to release the bound 14C label in a first order process characterized by half-lives of 10 to 300 min at 37 degrees C. Denaturation of the penicilloyl.penicillin-binding proctein complex prevented this release, indicating that the process is enzyme-catalyzed. [14C]Phenylacetylglycine was identified as the major labeled fragmentation product, indicating that these cephalosporin-sensitive penicillin-binding proteins, for which no in vitro transpeptidase or carboxypeptidase activity has been found, catalyze the same fragmentation of the bound penicilloyl moiety previously described for several penicillin-sensitive D-alanine carboxypeptidases.     

Active site-directed photoaffinity labeling and partial characterization of oligosaccharyltransferase

Oligosaccharyltransferase, the enzyme that catalyzes the transfer of the oligosaccharide chain of dolichol-P-P-GlcNAc2Man9Glc3 to asparagine residues in -Asn-X-Thr/Ser- sites within polypeptides, has been radiolabeled using a photoactivatable azido tripeptide acceptor, N alpha-[3H]Ac-Asn-Lys(N epsilon-p-azidobenzoyl)-Thr-NH2. As determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the molecular mass of the oligosaccharyltransferase polypeptide from hen oviduct microsomes is 60 kDa. Radiolabeling of the 60-kDa polypeptide was completely dependent upon photolysis of hen oviduct endoplasmic reticulum preparations in the presence of the azido peptide and Mn2+, which is required for enzymatic activity. Labeling of the enzyme was not inhibited in the presence of a 10-fold excess of the nonacceptor peptides, unacetylated Asn-Lys(N epsilon-p-azidobenzoyl)-Thr-NH2 or unacetylated Asn-Leu-Thr-NH2, whereas it was completely abolished by the presence of a 10-fold excess of the competing acceptor peptide, N alpha-Bz-Asn-Leu-Thr-NH2. Thermal inactivation of oligosaccharyltransferase was achieved by heating endoplasmic reticulum preparations to 60 degrees C. This loss of enzyme activity at 60 degrees C paralleled a comparable decrease in radiolabeling of the 60-kDa polypeptide, whereas temperatures of 50 degrees C and lower had no effect on either process. Oligosaccharyltransferase itself may be an N-linked glycoprotein, because the 60-kDa radiolabeled polypeptide binds to concanavalin A-agarose and is susceptible to digestion by beta-endohexosaminidase H.     

Regulation of dolichyl phosphate-mediated protein glycosylation: estrogen effects on glucosyl transfers in oviduct membranes

Regulation of Glc transfer from UDP-Glc via Glc-P-Dolichol to form Glc3-Man9-oligosaccharide-lipid has been studied during estrogen-induced chick oviduct differentiation. The process was studied as two distinct reactions: transfer of Glc from UDP-Glc to Dol-P, forming Glc-P-Dol; and transfer of Glc from Glc-P-Dol to Man9-OL (oligosaccharide-lipid), forming a series of glucosylated oligosaccharide-lipids. Kinetic analysis of [14C]Glc transfer from UDP-[14C]Glc to endogenous Dol-P shows that Dol-P is limiting in membrane preparations and that, concomitant with estrogen-induced differentiation, there is an increase in Dol-P available for Glc transfers. There is also greater glucosyl transferase activity present in membranes from mature hens and estrogenized chicks than in membranes from immature chicks. In order to study the second phase of glucosylation, transfer to the oligosaccharide, it was necessary to develop an assay in which membranes could be reacted with exogenously added substrates, [14C]Glc-P-Dol and [3H]Man9-OL. This reaction is dependent on detergent (0.02% NP-40 was used) and is stimulated by EDTA. The apparent Km for Glc-P-Dol was about 1.5 microM. A series of double-labeled oligosaccharides having sizes consistent with Glc1-, Glc2-, and Glc3-Man9-OL were formed. Chemical and enzymatic analysis of [14C]Glc oligosaccharides formed by incubation with the exogenous substrates, or by incubation with UDP-[14C]Glc and endogenous acceptors, indicated that the glucosylated oligosaccharides were similar. Assays of membranes from estrogenized chicks, mature hens, and hormone-withdrawn chicks showed increased glucosyl transferase activity upon hormone treatment. Similar assays in the absence of exogenous Man9-OL indicated that hormone treatment was also accompanied by increased levels of endogenous oligosaccharide-lipid acceptors.     

Biosynthesis of the core region of yeast mannoproteins. Formation of a glucosylated dolichol-bound oligosaccharide precursor, its transfer to protein and subsequent modification

A new membrane preparation from Saccharomyces cerevisiae was developed, which effectively catalyzes the synthesis of large oligosaccharide-lipids from GDP-Man and UDP-Glc allowing a detailed study of their formation and size. The oligosaccharide from an incubation with GDP-Man could be separated by gel filtration chromatography into several species consisting of two N-acetylglucosamine (GlcNAc) residues at the reducing end and differing by one mannos unit; the major compound formed has the composition (Man)9(GlcNAc)2. Upon incubation with UDP-Glc, three oligosaccharides corresponding to the size of (Glc)1-3(Man)9(GlcNAc)2 are formed. Thus, the oligosaccharides generated in vitro by the yeast membranes appear to be identical in size with the oligosaccharides found in animal systems. In addition the results indicate that dolichyl phosphate mannoe (DolP-Man) is the immediate donor in assembling the oligosaccharide moiety from (Man)5(GlcNAc)2 to (Man)9(GlcNAc)2. All three glucose residues are transferred from DolP-Glc. Experiments with isolated [Glc-14C]oligosaccharide-lipid as substrate demonstrated that the oligosaccharide chain is transferred to an endogenous membrane protein acceptor. Moreover, transfer is followed by an enzymic removal of glucose residues, due to a glucosidase activity associated with the membranes. Glucose release from the free [Glc-14C]oligosaccharide is less effective than from protein-bound oligosaccharide. Glycosylation was also observed using [Man-14C]oligosaccharide-lipid or DolPP-(GlcNAc)2 as donor. However, transfer in the presence of glucose seems to be more rapid. The mannose-containing oligosaccharide, released from the lipid, was shown to function as a substrate for further chain elongation reactions utilizing GDP-Man but not DolPP-Man as donor. It is suggested that the immediate precursor in the synthesis of the heterogeneous core region, (Man)12-17(GlcNAc)2, of yeast mannoproteins is a glucose-containing lipid-oligosaccharide with the composition (Glc)3(Man)9(GlcNAc)2, i.e. only part of what has been defined as inner core is built up on the lipid carrier. After transfer to protein the oligosaccharide is modified by excision of the glucose residues, followed subsequently by further elongation from GDP-Man to give the size of th oligosaccharide chains found in native mannoproteins.     

Different Polypeptides Are Rapidly Transported in Auditory and Optic Neurons

Abstract: Rapidly transported proteins and glycoproteins in the auditory and optic nerves of the guinea pig were analyzed by electrophoresis and two-dimensional electrofocusing/electrophoresis. Proteins transported in the auditory nerve were analyzed in the cochlear nucleus 3 h after cochlear injection of radioactive precursor, and proteins transported in the optic nerve were analyzed in the superior colliculus 6 h after intraocular injection of radioactive precursor. Two-dimensional analysis showed that several rapidly transported polypeptides were present in one system, but not in the other. By use of [³H]fucose as a precursor or by separating [³⁵S]methionine-labeled polypeptides on immobilized concanavalin A or wheat germ agglutinin, it was shown that most of the proteins transported in only one system are glycoproteins. As previously reported a polypeptide of molecular weight 140,000 was a major labeled species in the auditory nerve. This polypeptide was also found in the optic nerve, but only as a minor species. Two other polypeptides with molecular weights and isoelectric points similar to those of the 140,000 molecular weight polypeptide were present in both systems, but were much more abundant in the optic nerve. The major labeled polypeptide in both systems had a molecular weight of 25,000.     

Metabolism of 2-deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose in yeast and chick-embryo cells.

2-Deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose have been prepared by tritiation of the corresponding unlabeled 2-fluoro sugars. The tritiated 2-fluoro sugars are phosphorylated and activated by UTP and by GTP to yield UDP-2-deoxy-2-fluoro-D-[3H]glucose, UDP-2-deoxy-2-fluoro-D-[3H]mannose, GDP-2-deoxy-2-fluoro-D-[3H]glucose and GDP-2-deoxy-2-fluoro-D-[3H]mannose in both cell types. The nucleotide derivatives could also be labeled in the nucleotide moiety by feeding the cells with [14C]uridine or [14C]guanosine in the presence of unlabeled 2-fluoro sugar. No evidence was obtained for metabolic steps in which the six-carbon chain of 2-fluoro sugars was not preserved. No epimerisation of the label to 2-deoxy-2-fluoro-D-[3H]galactose could be observed by radioactive gas-liquid chromatography of the enzymatic cleavage products of the different 2-fluoro sugar metabolites isolated from either cell type. Yeast and chick embryo cells both incorporate 2-deoxy-2-fluoro-D-[3H]glucose and 2-deoxy-2-fluoro-D-[3H]mannose specifically into glycoproteins, although this incorporation is very low when compared to the incorporation of 2-deoxy-D-[3H]glucose.     

Incorporation of [C]Glucosamine and [C]Mannose into Glycolipids and Glycoproteins in Cotyledons of Pisum sativum L

Developing pea cotyledons incorporate radioactivity in vivo from [¹⁴C]glucosamine and [¹⁴C]mannose into glycolipids and glycoproteins. Several different lipid components are labeled including neutral, ionicnonacidic, and acidic lipids. The acidic lipids labeled in vivo appear similar to the polyisoprenoid lipid intermediates formed in vitro in pea cotyledons. Radioactivity from [¹⁴C]glucosamine and [¹⁴C]mannose is also incorporated into glycopeptides. Considerable redistribution of [¹⁴C]mannose into other glycosyl components found in endogenous glycoproteins is observed. An N-acetylglucosamine to asparagine glycopeptide linkage has been isolated from [¹⁴C]glucosamine-labeled glycoproteins.     

In vivo labeling of myelin lipids and proteolipid protein with [3H]myristate, [14C]linoleate,and [14C]linolenate

To investigate the incorporation of essential fatty acids into myelin components, 24-day-old rabbits were injected intracerebrally with [¹⁴C]linoleate, [¹⁴C]linolenate, or [³H]Myristate for comparison. Animals were killed 22 hr later and myelin was isolated. [³H]myristate labeled all myelin lipids including monogalactosyl diglyceride, with the exception of sulfatides. With¹⁴C-essential fatty acids, only glycerophospholipids were efficiently labeled and their specific activities were in the following decreasing orders: PC>PI>PE>PS with [¹⁴C]linoleate, and PE>PC>PI=PS with [¹⁴C]linolenate. Among myelin proteins, PLP and DM-20 were labeled with all 3 precursors. PLP was purified from myelin labeled with¹⁴C-essential fatty acids. The label was then cleaved from the protein by alkaline methanolysis and was identified as a dienoic ([¹⁴C]linoleate) or a tetraenoic ([¹⁴C]linolenate) fatty acid. MBP was not labeled with [³H]myristate, but was slightly labeled with both¹⁴C-essential fatty acids. The signification of the latter result is discussed.Abbreviations FA fatty acid(s) - HPTLC high-performance thin-layer chromatography - MBP myelin basic protein - PLP proteolipid protein - PC phosphatidylcholine - PE phosphatidylethanolamine and ethanolamine plasmalogens - PI phosphatidylinositol - PS phosphatidylserine - SDS sodium dodecylsulfate     

Low molecular weight GTP-binding proteins in cardiac muscle. Association with a 32-kDa component related to connexins.

Low molecular weight GTP-binding proteins and their cellular interactions were examined in cardiac muscle. Heart homogenate was separated into various subcellular fractions by differential and sucrose density gradient centrifugation. Various fractions were separated by sodium dodecyl sulfate-gel electrophoresis, blotted to nitrocellulose, and GTP-binding proteins detected by incubating with [alpha-32]GTP. Three polypeptides of M(r) 23,000, 26,000, and 29,000 were specifically labeled with [alpha-32P]GTP in all the fractions examined and enriched in sarcolemmal membranes. The 23-kDa polypeptide was labeled to a higher extent with [alpha-32P]GTP than the 26- and 29-kDa polypeptides. A polypeptide of M(r) 40,000 was weakly labeled with [alpha-32P]GTP in the sarcolemmal membrane and tentatively identified as Gi alpha by immunostaining with anti-Gi alpha antibodies. Cytosolic GTP-binding proteins were labeled with [alpha-32P]GTP and their potential sites of interaction investigated using the blot overlay approach. A polypeptide of 32 kDa present in sarcolemmal membranes, intercalated discs, and enriched in heart gap junctions was identified as a major site of interaction. The low molecular weight GTP-binding proteins associated with the 32-kDa polypeptide through a complex involving cytosolic components of M(r) 56,000, 36,000, 26,000, 23,000, and 12,000. A monoclonal antibody against connexin 32 from liver strongly recognized the 32-kDa polypeptide in heart gap junctions, whereas polyclonal antibodies only weakly reacted with this polypeptide. The low molecular weight GTP-binding proteins associated with a 32-kDa polypeptide in liver membranes that was also immunologically related to connexin 32. These results indicate the presence of a subset of low molecular weight GTP-binding proteins in a membrane-associated and a cytoplasmic pool in cardiac muscle. Their association with a 32-kDa component that is related to the connexins suggests that these polypeptides may be uniquely situated to modulate communication at the cell membrane.     

Biosynthesis of lipophosphoglycan from Leishmania donovani: characterization of mannosylphosphate transfer in vitro.

Lipophosphoglycan (LPG) is the major surface glycoconjugate of Leishmania donovani promastigotes and is composed of a capped polymer of repeating PO4-6Gal(beta 1,4)Man alpha 1 disaccharide units linked via a phosphosaccharide core to a lyso-1-O-alkylphosphatidylinositol anchor. An exogenous acceptor composed of the glycolipid anchor portion of LPG was shown to stimulate the enzymatic synthesis of the repeating phosphorylated disaccharide units of LPG in a cell-free system. Using the exogenous acceptor, GDP-[3H]Man, [beta-32P]GDP-Man, and unlabeled UDP-Gal as substrates, membrane preparations from an LPG-defective mutant of L. donovani that lacks endogenous acceptors catalyzed the incorporation of the doubly labeled mannosylphosphate unit into a product that exhibited the chemical and chromatographic characteristics of LPG. Analysis of fragments generated by mild acid hydrolysis of the radiolabeled product indicated that [3H]mannose-1-[32P]PO4 had been transferred from the dual-labeled sugar nucleotide. These results are consistent with the proposal that the repeating units of the L. donovani LPG are synthesized by the alternating transfer of mannose 1-phosphate and galactose from their respective nucleotide donors.     

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.     

Thermophilic Anaerobic Biodegradation of [14C]Lignin, [14C]Cellulose, and [14C]Lignocellulose Preparations

Thermophilic (55°C) anaerobic enrichment cultures were incubated with [¹⁴C-lignin]lignocellulose, [¹⁴C-polysaccharide]lignocellulose, and kraft [¹⁴C]lignin prepared from slash pine, Pinus elliottii, and ¹⁴C-labeled preparations of synthetic lignin and purified cellulose. Significant but low percentages (2 to 4%) of synthetic and natural pine lignin were recovered as labeled methane and carbon dioxide during 60-day incubations, whereas much greater percentages (13 to 23%) of kraft lignin were recovered as gaseous end products. Percentages of label recovered from lignin-labeled substrates as dissolved degradation products were approximately equal to percentages recovered as gaseous end products. High-pressure liquid chromatographic analyses of CuO oxidation products of sound and degraded pine lignin indicated that no substantial chemical modifications of the remaining lignin polymer, such as demethoxylation and dearomatization, occurred during biodegradation. The polysaccharide components of pine lignocellulose and purified cellulose were relatively rapidly mineralized to methane and carbon dioxide; 31 to 37% of the pine polysaccharides and 56 to 63% of the purified cellulose were recovered as labeled gaseous end products. An additional 10 to 20% of the polysaccharide substrates was recovered as dissolved degradation products. Overall, these results indicate that elevated temperatures can greatly enhance rates of anaerobic degradation of lignin and lignified substrates to methane and low-molecular-weight aromatic compounds.