Arabinoxylan biosynthesis in wheat. Characterization of arabinosyltransferase activity in Golgi membranes

Arabinoxylan arabinosyltransferase (AX-AraT) activity was investigated using microsomes and Golgi vesicles isolated from wheat (Triticum aestivum) seedlings. Incubation of microsomes with UDP-[(14)C]-beta-L-arabinopyranose resulted in incorporation of radioactivity into two different products, although most of the radioactivity was present in xylose (Xyl), indicating a high degree of UDP-arabinose (Ara) epimerization. In isolated Golgi vesicles, the epimerization was negligible, and incubation with UDP-[(14)C]Ara resulted in formation of a product that could be solubilized with proteinase K. In contrast, when Golgi vesicles were incubated with UDP-[(14)C]Ara in the presence of unlabeled UDP-Xyl, the product obtained could be solubilized with xylanase, whereas proteinase K had no effect. Thus, the AX-AraT is dependent on the synthesis of unsubstituted xylan acting as acceptor. Further analysis of the radiolabeled product formed in the presence of unlabeled UDP-Xyl revealed that it had an apparent molecular mass of approximately 500 kD. Furthermore, the total incorporation of [(14)C]Ara was dependent on the time of incubation and the amount of Golgi protein used. AX-AraT activity had a pH optimum at 6, and required the presence of divalent cations, Mn(2+) being the most efficient. In the absence of UDP-Xyl, a single arabinosylated protein with an apparent molecular mass of 40 kD was radiolabeled. The [(14)C]Ara labeling became reversible by adding unlabeled UDP-Xyl to the reaction medium. The possible role of this protein in arabinoxylan biosynthesis is discussed.     

Substrate specificity of the alpha-L-arabinofuranosidase from Rhizomucor pusillus HHT-1

The alpha-L-arabinofuranosidase (AF) from the fungus Rhizomucor pusillus HHT-1 released arabinose at appreciable rates from (1-->5)-alpha-L-arabinofuranooligosaccharides, sugar beet arabinan and debranched arabinan. This enzyme preferentially hydrolyzed the terminal arabinofuranosyl residue [alpha-(1-->5)-linked] of the arabinan backbone rather than the arabinosyl side chain [alpha-(1-->3)-linked residues]. The enzyme-hydrolyzed arabinan reacted at and debranched the arabinan almost at the same rate, and the degree of conversion for both cases was 65%. Methylation analysis of arabinan showed that the arabinosyl-linkage proportions were 2:2:2:1, respectively, for (1-->5)-Araf, T-Araf, (1-->3, 5)-Araf and (1-->3)-Araf, while the ratios for the AF-digested arabinan shifted to 3:1:2:1. Enzyme digestion resulted in an increase in the proportion of (1-->5)-linked arabinose and a decrease in the proportion of terminal arabinose indicated this AF cleaved the terminal arabinosyl residue of the arabinan back bone [alpha-(1-->5)-linked residues]. Peak assignments in the 13C NMR spectra also confirmed this linkage composition of four kinds of arabinose residues. Both 1H and 13C NMR spectra are dominated by signals of the alpha-anomeric configuration of the arabinofuranosyl moieties. No signals were recorded for arabinopyranosyl moieties in the NMR spectra. Methylation and NMR analysis of native and AF-digested arabinan revealed that this alpha-L-arabinofuranosidase can only hydrolyse alpha-L-arabinofuranosyl residues of arabinan.     

In vitro biosynthesis of galactans by membrane-bound galactosyltransferase from radish (<Emphasis Type="Italic">Raphanus sativus</Emphasis> L.) seedlings

We investigated a galactosyltransferase (GalT) involved in the synthesis of the carbohydrate portion of arabinogalactan-proteins (AGPs), which consist of a beta-(1-->3)-galactan backbone from which consecutive (1-->6)-linked beta-Gal p residues branch off. A membrane preparation from 6-day-old primary roots of radish ( Raphanus sativus L.) transferred [(14)C]Gal from UDP-[(14)C]Gal onto a beta-(1-->3)-galactan exogenous acceptor. The reaction occurred maximally at pH 5.9-6.3 and 30 degrees C in the presence of 15 mM Mn(2+) and 0.75% Triton X-100. The apparent K(m) and V(max) values for UDP-Gal were 0.41 mM and 1,000 pmol min(-1) (mg protein)(-1), respectively. The reaction with beta-(1-->3)-galactan showed a bi-phasic kinetic character with K(m) values of 0.43 and 2.8 mg ml(-1). beta-(1-->3)-Galactooligomers were good acceptors and enzyme activity increased with increasing polymerization of Gal residues. In contrast, the enzyme was less efficient on beta-(1-->6)-oligomers. The transfer reaction for an AGP from radish mature roots was negligible but could be increased by prior enzymatic or chemical removal of alpha- l-arabinofuranose (alpha- l-Ara f) residues or both alpha- l-Ara f residues and (1-->6)-linked beta-Gal side chains. Digestion of radiolabeled products formed from beta-(1-->3)-galactan and the modified AGP with exo-beta-(1-->3)-galactanase released mainly radioactive beta-(1-->6)-galactobiose, indicating that the transfer of [(14)C]Gal occurred preferentially onto consecutive (1-->3)-linked beta-Gal chains through beta-(1-->6)-linkages, resulting in the formation of single branching points. The enzyme produced mainly a branched tetrasaccharide, Galbeta(1-->3)[Galbeta(1-->6)] Galbeta(1-->3)Gal, from beta-(1-->3)-galactotriose by incubation with UDP-Gal, confirming the preferential formation of the branching linkage. Localization of the GalT in the Golgi apparatus was revealed on a sucrose density gradient. The membrane preparation also incorporated [(14)C]Gal into beta-(1-->4)-galactan, indicating that the membranes contained different types of GalT isoform catalyzing the synthesis of different types of galactosidic linkage.     

Enzymatic synthesis and purification of uridine diphospho-beta-l-arabinopyranose, a substrate for the biosynthesis of plant polysaccharides

Many plant cell wall components such as the polysaccharides xylans and pectins or the glycoproteins arabinogalactan proteins and extensins contain arabinosyl residues. The arabinosyl substituents are thought to be incorporated into these wall polymers by the action of arabinosyltransferases using UDP-l-arabinose as the precursor. UDP-l-arabinose is not commercially available and therefore a procedure for generating UDP-l-arabinose was developed for use in studies on the biosynthesis of the arabinose-containing polymers. In this procedure UDP-d-xylose is incubated with an enzyme preparation from wheat germ and the nucleotide sugars in the reaction mixture are extracted. High-performance anion-exchange chromatography of the extract resolves two major UV-absorbing components: one corresponding to UDP-xylose and a second that elutes earlier. TLC analysis of collected and hydrolyzed fractions demonstrated the presence of l-arabinose in the early eluting fraction. Further analysis by NMR identified the compound as UDP-beta-l-arabinopyranose. The procedure reported here provides an efficient method for preparing either radioactive UDP-l-[(14)C]arabinose or nonradioactive UDP-l-arabinose and can also be used as an assay for UDP-xylose-4-epimerase activity.     

Biosynthesis of pentosyl lipids by pea membranes.

Pea membranes were incubated with UDP-[14C]xylose or UDP-[14C]arabinose and sequentially extracted with chloroform/methanol/water (10:10:3, by vol.) and sodium dodecyl sulphate (2%, w/v). An active epimerase in the membranes rapidly interconverted the two pentosyl nucleotides. Chromatographic analysis of the lipid extract revealed that both substrates gave rise to xylose- and arabinose-containing neutral lipids, xylolipid with properties similar to a polyisoprenol monophosphoryl derivative, and highly charged lipid-linked arabinosyl oligosaccharide. When UDP-[14C]pentose or the extracted lipid-linked [14C]arabinosyl oligosaccharide were used as substrates, their 14C was also incorporating into sodium dodecyl sulphate-soluble and -insoluble fractions as major end products. Polyacrylamide-gel electrophoresis of sodium dodecyl sulphate-soluble products indicated the formation of mobile components with Mr values between 40 000 and 200 000 (Sepharose CL-6B). The lipid-linked [14C]arabinosyl oligosaccharide possessed properties comparable with those of unsaturated polyisoprenyl pyrophosphoryl derivatives. It was hydrolysed by dilute acid to a charged product (apparent Mr 2300) that could be fractionated in alkali. It was degraded to shorter labelled oligosaccharides by slightly more concentrated acid and eventually to [14C]arabinose as the only labelled component. Susceptibility to acid hydrolysis, and methylation analysis, indicated that the oligosaccharide contained approximately seven sequential alpha-1,5-linked arabinofuranosyl units at the non-reducing end. Several acidic residues appear to be interposed between the terminal arabinosyl units and the charged lipid.     

Arabidopsis family GT43 members are xylan xylosyltransferases required for the elongation of the xylan backbone

Xylan is the second most abundant polysaccharide in plant biomass targeted for biofuel production. Therefore, it is imperative to understand the biochemical mechanism underlying xylan biosynthesis. Although previous genetic studies have identified several genes implicated in xylan biosynthesis, biochemical proof of any of their encoded proteins as a xylan xylosyltransferase (XylT) responsible for xylan backbone biosynthesis is still lacking. In this study, we investigated the enzymatic activities of two Arabidopsis thaliana GT43 members, IRX9 (Irregular Xylem9) and IRX14, which have been genetically shown to be non-redundantly involved in the elongation of the xylan backbone. IRX9 and IRX14, alone or simultaneously, were heterologously expressed in tobacco BY2 cells, and microsomes isolated from the transgenic BY2 cells were tested for XylT activity using xylotetraose (Xyl(4)) as an acceptor and UDP-[(14)C]xylose as a donor. It was found that although microsomes with expression of IRX9 or IRX14 alone exhibited little incorporation of radiolabeled xylose, a high level of incorporation of radiolabeled xylose onto Xyl(4) was conferred by microsomes with co-expression of IRX9 and IRX14. Further analysis using fluorescent anthranilic acid-labeled xylotetraose (Xyl(4)-AA) as an acceptor revealed that up to five β-(1,4)-linked xylosyl residues were able to be transferred onto Xyl(4)-AA by microsomes with co-expression of IRX9 and IRX14. Furthermore, it was shown that xylooligomers ranging from Xyl(3)-AA to Xyl(6)-AA could all be used as acceptors for the xylosyl transfer by microsomes with co-expression of IRX9 and IRX14. Together, these findings provide the first biochemical evidence that IRX9 and IRX14 are xylosyltransferases that operate cooperatively in the elongation of the xylan backbone.     

Development of a filter assay for measuring homogalacturonan: alpha-(1,4)-Galacturonosyltransferase activity

Alpha-(1,4)-galacturonosyltransferases (GalATs) catalyze the addition of (1,4)-linked alpha-D-galacturonosyl residues onto the nonreducing end of homogalacturonan chains. The nucleotide-sugar donor for the enzymatic reaction is uridine diphospho-D-galactopyranosyluronic acid (UDP-D-GalpA). Many GalAT activity assays are based on the incorporation of D-[(14)C]GalpA from UDP-D-[(14)C]GalpA onto exogenously added homogalacturonan acceptors. Reactions based on this method can be time-consuming because multiple labor-intensive centrifugations and washes with organic solvents are required to remove the unincorporated UDP-D-[(14)C]GalpA from the (14)C-labeled products. Here we report the development of an alternative GalAT filter assay based on the ability of homogalacturonan to bind to cetylpyridinium chloride (CPC). GalAT assay reaction products made using radish (Raphanus sativus) microsomal membranes or solubilized proteins from tobacco (Nicotiana tabacum L. cv. Samsun) and Arabidopsis thaliana (cv. Columbia) were spotted onto Whatman 3MM paper treated with 2.5% (w/v) CPC. Unincorporated UDP-D-[(14)C]GalpA was selectively removed from the filters by washing with 150-250 mM NaCl. The versatility of this assay is demonstrated by using it to identify GalAT activity in fractions obtained during the partial purification of tobacco GalAT by SP Sepharose cation exchange chromatography and by detecting the GalAT-catalyzed incorporation of D-[(14)C]GalpA onto endogenous acceptors from Arabidopsis membranes.     

Composition of the cell walls of different asparagus (Asparagus officinalis) tissues

Portions of stems from the base of asparagus spears (Asparagus officinalis L. cv. Connovor Collossus) were dissected to give the following tissues: (1) pith, which was free of vascular bundles, (2) two surrounding layers, parenchyma and fibre I and II (PFI and PFII), containing parenchyma and vascular bundles, (3) sclerenchyma sheath, (4) epidermis and sub-epidermal layers and (5) asparagus vascular fibre (AVF). The alcohol-insoluble residues (AIRs) from these tissues were shown to be free of starch. They were analysed for moisture and protein, and the component sugars were released by two hydrolytic procedures, which helped to distinguish the sugars from non-cellulosic polysaccharides and cellulose. The AIRs from pith and epidermal tissues were relatively low in xylose, but were rich in cellulosic glucose, and sugars associated with pectic polysaccharides such as galacturonic acid, galactose and arabinose. Their major component polysaccharides (in decreasing amounts) were inferred to be pectic polysaccharides, cellulose, and hemicelluloses. AIR from sclerenchyma was rich in glucose and xylose, suggesting the presence of much cellulose and (acidic) xylans. The AIRs of PFI, PFII and AVF contained significant amounts of xylose in addition tn other sugars, and the major polysaccharides inferred to be present were pectic polysaccharides, cellulose and hemicelluloses, a significant proportion of which may be acidic xylans. Methylation analysis of the AIRs confirmed the above inferences. The bulk of the glucosyl residues were (1–4)-linked, and there were small but significant amounts of (1–4, 6)-linked glucosyl residues (the linkage characteristic of xyloglucans) in all the preparations. The presence of (1–4)-linked galactosyl, (1–5)-linked arabinosyl, terminal galactosyl, terminal arabinosyl, (1–2)- and (1–2, 4)-linked rhamnosyl residues in all the AIRs except that from sclerenchyma, confirmed the presence of significant levels of pectic polysaccharides in all the parenchyma tissues. All the preparations containing vascular tissues contained significant amounts of (1–4)-linked xylosyl residues, probably derived from acidic xylans. Even in the AIR of pith, a significant amount of (1–4)-linked xylosyl residues were detected. This may be due to the ability of these cells and the parenchyma cells associated with the vascular bundles, to undergo lignification in mature asparagus plants.     

Participation of the microsomal CDP-diglycerides in the mitochondrial biosynthesis of phosphatidylglycerol

Participation of microsomal CDP-diglycerides in mitochondrial biosynthesis of phosphatidylglycerol was studied by [3H]palmitoyl, [14C]linoleoyl, and [14C]arachidonoyl CDP-diglycerides and [3H]CDP-diglycerides which were bound to microsomal membranes, incubated with unlabelled mitochondrial membranes, and further incubated in the presence of radioactive sn-glycero-3-phosphate under conditions required for mitochondrial phosphatidylglycerol biosynthesis. Ten to 15% of microsomal radioactive CDP-diglycerides was transferred to mitochondrial membranes and incorporated into mitochondrial radioactive lipids identified as phosphatidylglycerol, phosphatidylglycerophosphate, and, when [14C]linoleoyl CDP-diglycerides were used, diphosphatidylglycerol (cardiolipin).     

The formation of a β-(1→4)-d-galactan chain catalysed by a Phaseolus aureus enzyme

With a particulate enzyme preparation from Phaseolus aureus hypocotyls, UDP-alpha-d-[U-(14)C]galactose served as a precursor for a number of products. One of these products was characterized as a beta-(1-->4)-linked galactan. The ADP-, GDP-, TDP- and CDP- derivatives of alpha-d-galactose did not serve as biosynthetic precursors for any products insoluble in 70% ethanol, nor as substrates for a sugar nucleotide 4-epimerase which is present in the particulate enzyme preparation. The (14)C-labelled beta-(1-->4)-galactan is alkali-insoluble and was characterized by analysis of partial acetolysis products. The labelling pattern of the [(14)C]oligosaccharides derived from acetolysis indicates that (1) only slightly more than two [(14)C]galactose moieties are added to the growing polysaccharide chain on average, and (2) these additions take place at the reducing end of the polysaccharide chain. The radioactive beta-(1-->4)-linked galactan chain represented 8.5% of the radioactivity initially added, and 20% of the water- and butanol-insoluble products derived from UDP-alpha-d-[(14)C]galactose. Total hydrolysis of the alkali-insoluble fraction of Phaseolus aureus hypocotyl yielded d-glucose and d-mannose in a 5:1 ratio but no detectable quantities of d-galactose. A trace quantity of a radioactive disaccharide, identified as (1-->3)-linked galactobiose, was isolated from the partial acetolysate of the alkali-insoluble [(14)C]polysaccharide material. Also isolated from this partial acetolysate was a C-1 derivative of [(14)C]galactose, which could not be identified. An alkali-soluble galactose-containing polysaccharide was also synthesized in this enzymic reaction, and represented 20% of the water- and butanol-insoluble products derived from UDP-alpha-d-[(14)C]galactose. The spectrum of radioactive oligosaccharides produced by partial acetolysis of this alkali-soluble polysaccharide material was different from that obtained from the alkali-insoluble polysaccharide, indicating a different structure.     

Identification of a novel alpha(1-->6) mannopyranosyltransferase MptB from Corynebacterium glutamicum by deletion of a conserved gene, NCgl1505, affords a lipomannan- and lipoarabinomannan-deficient mutant

Mycobacterium tuberculosis and Corynebacterium glutamicum share a similar cell wall structure and orthologous enzymes involved in cell wall assembly. Herein, we have studied C. glutamicum NCgl1505, the orthologue of putative glycosyltransferases Rv1459c from M. tuberculosis and MSMEG3120 from Mycobacterium smegmatis. Deletion of NCgl1505 resulted in the absence of lipomannan (Cg-LM-A), lipoarabinomannan (Cg-LAM) and a multi-mannosylated polymer (Cg-LM-B) based on a 1,2-di-O-C(16)/C(18:1)-(alpha-D-glucopyranosyluronic acid)-(1-->3)-glycerol (GlcAGroAc(2)) anchor, while syntheses of triacylated-phosphatidyl-myo-inositol dimannoside (Ac(1)PIM(2)) and Man(1)GlcAGroAc(2) were still abundant in whole cells. Cell-free incubation of C. glutamicum membranes with GDP-[(14)C]Man established that C. glutamicum synthesized a novel alpha(1-->6)-linked linear form of Cg-LM-A and Cg-LM-B from Ac(1)PIM(2) and Man(1)GlcAGroAc(2) respectively. Furthermore, deletion of NCgl1505 also led to the absence of in vitro synthesized linear Cg-LM-A and Cg-LM-B, demonstrating that NCgl1505 was involved in core alpha(1-->6) mannan biosynthesis of Cg-LM-A and Cg-LM-B, extending Ac(1)PI[(14)C]M(2) and [(14)C]Man(1)GlcAGroAc(2) primers respectively. Use of the acceptor alpha-D-Manp-(1-->6)-alpha-D-Manp-O-C(8) in an in vitro cell-free assay confirmed NCgl1505 as an alpha(1-->6) mannopyranosyltransferase, now termed MptB. While Rv1459c and MSMEG3120 demonstrated similar in vitroalpha(1-->6) mannopyranosyltransferase activity, deletion of the Rv1459c homologue in M. smegmatis did not result in loss of mycobacterial LM/LAM, indicating a functional redundancy for this enzyme in mycobacteria.     

Hormonal effects on the biosynthesis of sulfated glycoprotein in a microsomal fraction of the endometrium of rabbit uterus

A crude microsomal fraction (M-Fr) was separated from the endometrial scrapings of uteri of ovariectomized rabbits with or without hormonal treatment. The effects of estrogen and progesterone on the incorporation into M-Fr of L-[U-14C]-fucose and N-acetyl-D-[6-3H]-glucosamine from their nucleotides were investigated. Estrogen increased the incorporation of these sugars, whereas progesterone suppressed this effect. The results of fractionation on a DEAE-Sephadex A-25 (Cl- form) column of the isotope-labelled complex saccharide mixtures, obtained by pronase digestion of the incubation mixtures, indicated that biosynthesis of sulfated glycoprotein was most sensitive to the hormones among the complex saccharides in M-Fr. Thus, a hormonal effects on the biosynthesis of sulfated glycoprotein in the endometrium of ovariectomized rabbit has been unambiguously confirmed at the microsomal level.     

Synthetic mannosides act as acceptors for mycobacterial alpha1-6 mannosyltransferase

A series of synthetic mannosides was screened in a cell-free system for their ability to act as acceptor substrates for mycobacterial mannosyltransferases. Evaluation of these compounds demonstrated the incorporation of [14C]Man from GDP-[14C]Man into a radiolabeled organic-soluble fraction and analysis by thin layer chromatography and autoradiography revealed the formation of two radiolabeled products. Each synthetic acceptor was capable of accepting one or two mannose residues, resulting in a major and a minor mannosylated product. Both products from each acceptor were isolated and their mass was confirmed by fast-atom bombardment-mass spectrometry (FABMS). Characterization of each mannosylated product by exo-glycosidase digestion. acetolysis and linkage analysis by gas chromatography mass spectrometry of partially per-O-methylated alditols, revealed only alpha1-6-linked products. In addition. the antibiotic amphomycin selectively inhibited the formation of mannosylated products suggesting polyprenolmonophosphate-mannose (C15 50-P-Man) was the immediate mannose donor in all mannosylation reactions observed. The ability of synthetic disaccharides to act as acceptor substrates in this system, is most likely due to the action of a mycobacterial polyprenol-P-Man:mannan alpha1-6 mannosyltransferase involved in the biosynthesis of linear alpha1-6-linked lipomannan.     

Structure and potential immunological activity of a pectin from Centella asiatica (L.) Urban

S3A was a RG-I pectin isolated from Centella asiatica that contained Rha, Ara, Gal, Glc and GalA in molar ratio of 1.0:0.6:1.5:0.2:1.1 and had been found to have a backbone composed mainly of the disaccharide repeat unit, -->4)-alpha-D-GalpA-(1-->2)-alpha-L-Rhap-(1-->. Based on methylation analysis, NaIO4 oxidation, partial acid hydrolysis and lithium-treatment, the structural features were elucidated. Side chains of S3A were predominantly linked to O-4 of 1,2,4-linked alpha-L-Rhap. The side chains are comprised of arabinosyl chains, galactosyl chains, arabinogalactosyl chains and short glucosyl chains. A total of 45% Rhap in the backbone was substituted by side chains. The arabinosyl residues were mostly distributed in the arabinosyl side chains. According to the immunological results of S3A and its degraded derivatives, S3A had no immunological activity, but its derivatives had immuno-stimulating activities to some extent.     

Structural characterisation of the olive pomace pectic polysaccharide arabinan side chains

An arabinan (97% of Ara and 3% of hexuronic acid) was isolated from the alcohol-insoluble residue (AIR) of olive pomace by treatment with 0.02 M HNO(3), at 80 degrees C, followed by graded precipitation with ethanol. It was separated from acidic pectic polysaccharides by anion-exchange chromatography, and by size-exclusion chromatography its molecular weight was estimated as 8.4 kDa. By methylation analysis, the linkage composition was established as 5:4:3:1 for (1-->5)-Araf, T-Araf, (1-->3,5)-Araf and (1-->3)-Araf, respectively. 13C NMR spectroscopy confirmed this linkage composition, and allowed to assign the alpha anomeric configuration for the arabinofuranosyl residues, except for some terminally linked ones, that were seen to occur as T-beta-Araf. By 2D NMR spectroscopy (1H and 13C), it was possible to conclude that the T-beta-Araf was (1-->5)-linked to a (1-->5)-Araf residue. Also, in the arabinan (1-->5)-Araf backbone, the branched (1-->3,5)-Araf residues were always adjacent to linear (1-->5)-Araf residues. A tentative structure is proposed.     

Biosynthesis of the fucose-containing xyloglucan nonasaccharide by pea microsomal membranes

Pea microsomal membranes catalyze the transfer of [¹⁴C]fucose (Fuc) from GDP-[U-¹⁴C]fucose, with or without added unlabeled UDP-glucose (Glc), UDP-xylose (Xyl) or UDP-galactose (Gal), to an insoluble product with properties characteristic of xyloglucan. After digestion of the ethanol-insoluble pellet with Streptomyces griseus endocellulase, [¹⁴C] fucose residues occur exclusively in a fragment corresponding in size to the xyloglucan nonasaccharide, Glc₄ Xyl₃ Gal Fuc. This fragment contains a single labeled fucose residue per oligomer, α-linked in a terminal nonreducing position. By comparison, in incubations where GDP-[¹⁴C] fucose is absent and replaced by UDP-[³H]xylose, the maximum size of labeled oligosaccharide found following cellulase digestion of products is an octasaccharide. In the presence of both GDP-[¹⁴C]fucose and UDP-[³H]xylose, a nonasaccharide containing the two labels is produced. Fucose and xylose residues are transferred within a few minutes to acceptor molecules of molecular weight up to 300,000. Such products do not elongate detectably over 60 minutes of incubation. The data support the conclusion that the nonasaccharide subunit of xyloglucan may be generated in vitro by transfucosylation to preformed acceptor chains, and that its synthesis is dependent on the inclusion of exogenous GDP-fucose.     

Initiation and synthesis of the Streptococcus pneumoniae type 3 capsule on a phosphatidylglycerol membrane anchor

The type 3 synthase from Streptococcus pneumoniae is a processive beta-glycosyltransferase that assembles the type 3 polysaccharide [3)-beta-D-GlcUA-(1-->4)-beta-D-Glc-(1-->] by a multicatalytic process. Polymer synthesis occurs via alternate additions of Glc and GlcUA onto the nonreducing end of the growing polysaccharide chain. In the presence of a single nucleotide sugar substrate, the type 3 synthase ejects its nascent polymer and also adds a single sugar onto a lipid acceptor. Following single sugar incorporation from either UDP-[(14)C]Glc or UDP-[(14)C]GlcUA, we found that phospholipase D digestion of the Glc-labeled lipid yielded a product larger than a monosaccharide, while digestion of the GlcUA-labeled lipid resulted in a product larger than a disaccharide. These data indicated that the lipid acceptor contained a headgroup and that the order of addition to the lipid acceptor was Glc followed by GlcUA. Higher-molecular-weight product synthesized in vitro was also sensitive to phospholipase D digestion, suggesting that the same lipid acceptor was being used for single sugar additions and for polymer formation. Mass spectral analysis of the anionic lipids of a type 3 S. pneumoniae strain demonstrated the presence of glycosylated phosphatidylglycerol. This lipid was also observed in Escherichia coli strains expressing the recombinant type 3 synthase. The presence of the lipid primer in S. pneumoniae membranes explained both the ability of the synthase to reinitiate polysaccharide synthesis following ejection of its nascent chain and the association of newly synthesized polymer with the membrane. Unlike most S. pneumoniae capsular polysaccharides, the type 3 capsule is not covalently linked to the cell wall. The present data indicate that phosphatidylglycerol may anchor the type 3 polysaccharide to the cell membrane.     

Solubilization of galactosyltransferase that synthesizes 1,4-beta-galactan side chains in pectic rhamnogalacturonan I

β -1,4-Galactan galactosyltransferase (GT) activity was solubilized from potato microsomal membranes in the presence of 78 m M 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulphonic acid. The solubilized GT activity transferred ¹⁴[C]galactose from UDP-¹⁴[C]galactose onto the acceptor-substrates composed of rhamnogalacturonan (RG) with short galactan chains (RG-A, approximately 1.2 MDa, mol% Gal/Rha = 0.7; RG-B, approximately 21 kDa, mol% Gal/Rha = 1.2). However, shorter RG containing short galactan chains (approximately 2 kDa and 1.2 kDa), RG oligomers without galactosyl-residues, galactan, and galactooligomers did not act as acceptor-substrates. Optimal pH for ¹⁴[C] incorporation onto RG-A and RG-B was around 5.6 and 7.5, respectively. The ¹⁴[C]-labelled products synthesized upon RG-A and RG-B could be digested with a RG specific lyase into smaller RG fragments. 1,4- β - Endog alactanase could not digest the former product, whereas the latter product was digested to ¹⁴[C]galactobiose and ¹⁴[C]galactose. This demonstrates that at least two GT activities were solubilized from potato microsomal membranes. One had optimal pH around 5.6 to transfer galactosyl residues onto RG-A, whereas the other had optimal pH around 7.5 to transfer galactosyl residues onto RG-B. Both synthesized galactan attached to the RG backbone of RG-A and RG-B, and the galactan synthesized onto the RG-B acceptor was 1,4- β -linked.     

Glucomannan Biosynthesis Catalyzed by Pisum sativum Enzymes

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

Phospholipid synthesis and exchange in isolated liver cells

1. The [(32)P]phosphate incorporated into the phospholipids of isolated rat hepatic cells is present in phosphatidic acid and to a smaller extent in phosphatidylinositol. 2. The ability to synthesize nitrogen-containing phospholipids is restored by adding a liver supernatant fraction, and it is suggested that the metabolic deficiency is caused by the leakage of cytoplasmic enzymes of the synthetase system from the cells. 3. Fortified cell preparations were pulse-labelled with [(32)P]phosphate, [Me-(14)C]choline, [2-(14)C]ethanolamine and [U-(14)C]inositol and the subsequent fate of the labelled microsomal and mitochondrial phospholipids followed. 4. A fall in the specific radioactivity of microsomal phospholipids and a rise in that of mitochondrial phospholipids is interpreted as providing evidence of a transfer of labelled phospholipid molecules from the synthetic site (endoplasmic reticulum) to the mitochondrial membranes in the intact cells. 5. The formation of the phospholipids of mitochondrial membranes is discussed.