Biosynthesis of T1 Antigen in Salmonella: Biosynthesis in a Cell-Free System

A particulate fraction from a T1 form of Salmonella typhimurium incorporated radioactivity from uridine diphosphate (UDP)-(14)C-glucose into products associated with the particulate enzyme. A major fraction of the incorporated radioactivity was found in the cell wall lipopolysaccharide fraction. Acid hydrolysis of incorporation products produced labeled galactose, ribose, and also glucose. The incorporation of glucose could be dissociated from the incorporation of galactose and ribose under certain conditions, and was assumed to represent incorporation into a polymer not related to T1 antigen. The incorporation of galactose and ribose probably represented the synthesis of T1 side chains of lipopolysaccharide, because (i) particulate fractions from non-T1 strains incorporated much less of these sugars and (ii) periodate oxidation and borohydride reduction converted a large portion of incorporated galactose residues into arabinose. The latter finding indicates that the galactose residues are galactofuranosides substituted either at C2 or C3; about 70% of the galactose residues in T1 side chains are known to be galactofuranosides substituted at C3. UDP-(14)C-galactose preparation used was not contaminated by UDP-(14)C-galactofuranose; therefore pyranose-to-furanose conversion must have taken place at some step during the reactions described above. The mechanism of conversion of galactose to ribose is not clear, but it was not found to involve a selective elimination of C1 or C6 of galactose or glucose.     

Patterns of incorporation of d-galactose into cell wall polysaccharide of growing maize roots

Summary ¹⁴C-1-d-galactose was rapidly taken up by excised corn root-tips and efficiently converted to hexose units in cell wall polysaccharides. The label recovered in both hydrolysed pectin and hemicellulose was predominantly in galactose and only the -cellulose contained appreciable amounts of labelled glucose. There was no evidence for breakdown of labelled units after incorporation into the cell wall. It is suggested that the utilisation of this free galactose has not appreciably affected the normal metabolic pathway by which galactose is incorporated into plant cell walls.Advantage was taken of the specificity of this labelling to follow patterns of galactosyl incorporation in roots. Autoradiographs were prepared from adjacent longitudinal sections that had been extracted with ammonium oxalate solution and 24% (w/v) KOH respectively. The distribution of silver grains over these sections was compared with that over an unextracted section. Galactosyl units of pectin were incorporated in young cell walls in all tissues investigated. The pattern closely resembled that noted in earlier work for uronosyl and pentosyl incorporation. In pith and cortical cells, galactosyl units of hemicellulose were deposited at a maximum rate in walls approaching the end of their growth when pentose incorporation was low. Because branched alkali-soluble polysaccharides containing galactose and pentose have been isolated from several tissues of corn, similar compounds are likely to exist in the root. It is proposed that the continued elaboration of such a polysaccharide might continue after deposition, and the addition of galactosyl units may be a factor which limits further plastic extension of the wall.     

The synthesis of exopolysaccharide by Klebsiella aerogenes membrane preparations and the involvement of lipid intermediates

1. Membrane preparations from Klebsiella aerogenes type 8 were shown to transfer glucose and galactose from their uridine diphosphate derivatives to a lipid and to polymer. The ratio of glucose to galactose transfer in both cases was 1:2. This is the same ratio in which these sugars occur in native polysaccharide. Galactose transfer was dependent on prior glucosylation of the lipid. Mutants were obtained lacking (a) glucosyltransferase and (b) galactosyltransferase. The transferase activities in a number of non-mucoid mutants was examined. 2. Glucose transfer was partially inhibited by uridine monophosphate, and incorporation of either glucose or galactose into lipid was decreased in the presence of uridine diphosphate. The sugars are thought to be linked to a lipid through a pyrophosphate bond, and treatment of the lipid intermediates with phenol yielded water-soluble compounds. These could be dephosphorylated with alkaline phosphatase. Transfer of glucuronic acid to lipid or polymer from uridine diphosphate glucuronic acid was much lower than that of the other two sugars. 3. The fate of sugars incorporated into polymer was also followed. Some conversion of glucose into galactose and glucuronic acid occurred. Mutants unable to transfer glucose or galactose to lipid were unable to form polymer. Other mutants capable of lipid glycosylation were in some cases unable to form polymer. A model for capsular polysaccharide synthesis is proposed and its similarity to the formation of other polymers outside the cell membrane is discussed.     

Soluble Cell Wall Polysaccharides Released from Pea Stems by Centrifugation : II. EFFECT OF ETHYLENE

The effect of ethylene on cell wall metabolism in sections excised from etiolated pea stems was studied. Ethylene causes an inhibition of elongation and a pronounced radial expansion of pea internodes as shown by an increase in the fresh weight of excised, 1-cm sections. Cell wall metabolism was studied using centrifugation to remove the cell wall solution from sections. The principal neutral sugars in the cell wall solution extracted with H₂O are arabinose, xylose, galactose, and glucose. Both xylose and glucose decline relative to controls in air within 1 hour of exposure to ethylene. Arabinose and galactose levels are not altered by ethylene until 8 hours of treatment, whereupon they decline in controls in air relative to ethylene treatment. When alcohol-insoluble polymers are fractionated into neutral and acidic polysaccharides, xylose and glucose predominate in the neutral fraction and arabinose and galactose in the acidic fraction. Ethylene depresses the levels of xylose and glucose in the neutral fraction and elevates arabinose and galactose in the acidic fraction. Ethylene treatment does not affect the level of uronic acids extracted with H₂O; however, the level of hydroxyproline-rich proteins in this water-extracted cell wall solution is increased by ethylene. Extraction of sections with CaCl₂ results in an increase in the levels of neutral sugars particularly arabinose. Ethylene depresses the yield of arabinose in calcium-extracted solution relative to controls in air. Similarly, extraction with CaCl₂ increases the yield of extracted hydroxyproline in ethanol-insoluble polymers and ethylene depresses its level relative to controls. Metabolism of uronic acids and neutral sugars and growth in response to ethylene treatment contrast markedly with auxin-induced polysaccharide metabolism and growth. With auxin, sections increase mostly in length not radius, and this growth form is associated with an increase in the levels of xylose, glucose, and uronic acids. With ethylene, on the other hand, stem elongation is suppressed and expansion is promoted, and this growth pattern is associated with a decrease in xylose and glucose in the ethanol-insoluble polysaccharides.     

Differential sensitivities to glucose and galactose repression of gluconeogenic and respiratory enzymes from Saccharomyces cerevisiae

The synthesis of isocitrate lyase was induced by the presence of ethanol in the chemostat reaching a specific activity of 200 mU·mg^-1 at this induced state. In glucoselimited, derepressed cells, 20 mU·mg^-1 were detected and under repressed conditions isocitrate lyase activity was not detected.The sensitivity of gluconeogenic enzymes: cytoplasmic malate dehydrogenase; fructose 1,6-bisphosphatase and isocitrate lyase as well as the mitochondrial enzymes NADH dehydrogenase and succinate cytochrome c oxidase to glucose and galactose repression were studied in chemostat cultures. Our results show that galactose was less effective as a repressor than glucose. Malate dehydrogenase was completely inactivated by glucose, whereas galactose only produced a 78% decrease of specific activity. Fructose 1,6-bisphosphatase and isocitrate lyase were completely inactivated by both sugars but at different rate. Glucose produced an 85% decrease of specific activity of the mitochondrial enzymes whereas galactose only decrease an 67%.     

Enzymes related to galactose utilization inPseudomonas cepacia

Pseudomonas cepacia produced a characteristic green sheen on EMB-galactose plates owing to production of galactonic acid by the constitutive membrane-associated glucose dehydrogenase of this bacterium. Mutants isolated as glucose dehydrogenase deficient (Gcd^–) also were deficient in membrane-associated galactose dehydrogenase. A strain that formed glucose dehydrogenase at 30°C but not at 40°C was also temperature sensitive with respect to formation of galactose dehydrogenase. The Gcd^– strains still utilized galactose. A second, NAD-specific, galactose dehydrogenase (not membrane associated) along with a transport system for galactose were induced during growth on galactose and constituted an alternative pathway of conversion of galactose to galactonate. Enzymes of the De Ley-Doudoroff pathway of conversion of galactonate to pyruvate and glyceraldehyde-3-phosphate were induced during growth on galactose. Unexpectedly, growth on galactose also elicited formation of enzymes of the Entner-Doudoroff (ED) route. Furthermore, mutants blocked in the ED pathway grew poorly on galactose. One interpretation of these findings is that glyceraldehyde-3-phosphate formed from galactose via the De Ley-Doudoroff route (by cleavage of 2-keto-3-deoxy-6-phosphogalaconate) is reconverted to hexose phosphate and metabolized via the ED pathway.     

Cell-Wall Changes in Potato Tuber Tissue 4Phytophthora infestans (Mont.) De Bary

Examination of the carbohydrates of cell walls prepared fromtuber discs of a susceptible variety of potato showed an increase,with time, in all the polysaccharide fractions in control discs,but a slower increase in the pectic fraction and a more rapidincrease in the extraction residue to discs infected with Phytophthorainfestans. These differences were related to the monosaccharidecomposition of hydrolysates; there was no increase in galactose,found predominantly in the pectic fraction, but a rapid increasein glucose which is confined almost exclusively to the extractionresidue. Part of the increased glucose was due to an accumulationof hyphal wall of P. infestans which contains mainly an alkali-insolubleglucan. Galactanase activity, which was demonstrated in infecteddiscs, could account for the divergence of galactose contentfrom that of the controls. There was an enhanced accumulationof a lignin-like polymer associated with the cell-wall fractionof infected discs.     

Capsular and extracellular polysaccharides of the diazotrophic rhizobacterium <Emphasis Type="Italic">Herbaspirillum seropedicae</Emphasis> Z78

The diazotrophic endophyte Herbaspirillum seropedicae Z78 was shown to possess a capsule containing two high-molecular-weight glycolipids, one of which was of a lipopolysaccharide nature. These glycolipids differed considerably in the fatty acid composition of their lipid components. The polysaccharide moiety of these glycans was composed of glucose, galactose, glucosamine, galactosamine, and a noncarbohydrate component, butanetetraol. In the culture liquid of H. seropedicae Z78, an extracellular polysaccharide and an extracellular form of lipopolysaccharide were revealed. Fatty acid composition of the extracellular lipopolysaccharide differed from that of the capsular glycoconjugates; the polysaccharide moiety of exoglycans contained only neutral sugars (mannose, glucose, and galactose) and a tetraatomic alcohol, butanetetraol. It is assumed that structural diversity of polysaccharide-containing polymers at the surface of H. seropedicae Z78 cells is conditioned by their different roles in plant colonization and formation of efficient symbiosis.     

Tracing cell wall biogenesis in intact cells and plants : selective turnover and alteration of soluble and cell wall polysaccharides in grasses

Cells of proso millet (Panicum miliaceum L. cv Abarr) in liquid culture and leaves of maize seedlings (Zea mays L. cv LH51 × LH1131) readily incorporated d-[U-¹⁴C]glucose and l-[U-¹⁴C]arabinose into soluble and cell wall polymers. Radioactivity from arabinose accumulated selectively in polymers containing arabinose or xylose because a salvage pathway and C-4 epimerase yield both nucleotide-pentoses. On the other hand, radioactivity from glucose was found in all sugars and polymers. Pulse-chase experiments with proso millet cells in liquid culture demonstrated turnover of buffer soluble polymers within minutes and accumulation of radioactive polymers in the cell wall. In leaves of maize seedlings, radioactive polymers accumulated quickly and peaked 30 hours after the pulse then decreased slowly for the remaining time course. During further growth of the seedlings, radioactive polymers became more tenaciously bound in the cell wall. Sugars were constantly recycled from turnover of polysaccharides of the cell wall. Arabinose, hydrolyzed from glucuronoarabinoxylans, and glucose, hydrolyzed from mixed-linkage (1→3, 1→4)β-d-glucans, constituted most of the sugar participating in turnover. Arabinogalactans were a large portion of the buffer soluble (cytoplasmic) polymers of both proso millet cells and maize seedlings, and these polymers also exhibited turnover. Our results indicate that the primary cell wall is not simply a sink for various polysaccharide components, but rather a dynamic compartment exhibiting long-term reorganization by turnover and alteration of specific polymers during development.     

Sugar compositions of extra- and intracellular polysaccharides produced by candida lipolytica (4124) grown on n-hexadecane

The free monosaccharide content of C. lipolytica (strain 4 124) cells grown on n-hexadecane was identified and found to be only glucose. The chromatographic analysis of the hydrolysate of intracellular cell wall polysaccharides indicated the presence of glucose: mannose: galactose: xylose in a ratio of 1 : 1.32 : 1.07 : 0.35. Paper and dise electrophoresis of extracellular polysaccharid from the culture broth was found to be heterogeneous. Ethanol fractionation separated it to a major component F (I) 81.99% and a minor one F (II) 13.04%. Analysis of the major fraction showed that it consisted of galactose and mannose only while the minor polysaccharide consisted of galactose, glucose and mannose. Thus it was concluded that the predominant sugar in both extracellular and intracellular polysaccharides was mannose. Xylose was detected in the intracellular polysaccharide only.     

Subapical Wall Synthesis and Wall Thickening Induced by Cycloheximide in Hyphae of Aspergillus nidulans

Hyphae of Aspergillus nidulans continued to synthesize all the major polysaccharide components of the cell wall when cycloheximide was added to cultures. In the presence of cycloheximide, hyphae did not elongate, but electron microscopy showed that the walls became thicker around the cell. The conclusion that cycloheximide changed wall synthesis from extension at the apex to subapical thickening was supported by grain distributions on radioautograms of mutant hyphae labeled with galactose. These findings are discussed in relation to the control of hyphal wall synthesis and are compared with the effects of protein synthesis inhibitors on wall formation in gram-positive bacteria.     

Oligoglucuronide production in Mucor rouxii: evidence for a role for endohydrolases in hyphal extension.

Culture filtrates of Mucor rouxii contained oligomers of glucuronic acid which were labeled rapidly during pulses with D-[U-14C]glucose. These oligomers were probably derived by enzymatic lysis of acidic polymers in the cell wall. The kinetics of the incorporation of label into oligouronides and cell wall polymers suggested that lysis of the wall was required for active hyphal extension. Experiments with cycloheximide, which inhibited hyphal extension, suggested that wall lysis was also required for the subapical cell wall synthesis which probably occurred under these conditions.     

Hyphal Wall Compositions of Marine and Terrestrial Fungi of the Genus Leptosphaeria

Hyphal wall compositions of six Leptosphaeria species were compared to assess whether gross changes have occurred in the hyphal wall chemistry of closely related fungi which have become ecologically restricted to marine or terrestrial habitats. Unfractionated, lipid-extracted hyphal walls of each Leptosphaeria species had qualitatively identical compositions consisting of glucose, mannose, galactose, glucosamine, amino acids, and traces of galactosamine. Quantitative analyses showed that the hyphal wall components varied from species to species. Qualitative compositions of alkali-soluble wall fractions from each species were identical and contained the same sugars found in the unfractionated walls. The alkali-insoluble residues contained glucose, glucosamine, and amino acids. The alkali-soluble fractions were composed predominantly of glucose, galactose, and mannose. The alkali-insoluble fractions contained high concentrations of glucose and glucosamine and relatively low concentrations of amino acids.     

STRUCTURE AND DISTRIBUTION OF GLUCOMANNAN AND SULFATED GLUCAN IN THE CELL WALLS OF THE RED ALGA KAPPAPHYCUS ALVAREZII (GIGARTINALES, RHODOPHYTA)

Two new polysaccharides were isolated from the cell walls of the carrageenan producing red seaweed Kappaphycus alvarezii (Doty) Doty. They were characterized by chemical analyses, enzymatic degradations, and nuclear magnetic resonance spectroscopy. One was a 4.0 M NaOH soluble β-(1,4)- d -glucomannan that mostly precipitated upon neutralization and dialysis. It was composed of about 82 residues, and 70% of its glucose and mannose were released by a commercial cellulase enzyme complex. The disaccharide β- d -Man (1→4) d -Glc was recovered from the hydrolysate during the first hours of degradation and confirmed the chemical structure of the polysaccharide. The other polysaccharide was extracted with 1.5 M NaOH and was identified as a sulfated glucan of degree of polymerization of about 180 1,4-linked β-glucose containing 10% 1,3-linkages. The sulfate was located on C-6 of 64% of the 4-linked glucose residues. A third alkali-soluble polysaccharide rich in galactose was also detected. The distribution of the glucomannan and galactose containing polysaccharides was inversely related to the algal cell size. Potential functions of these alkali-soluble polymers are discussed in the context of cell wall polysaccharide assembly.     

Investigations of mannan and glucan in the cell wall ofCandida boidinii cultivated on methanol

The polysaccharide components (mannan and glucan) in the cell wall ofCandida boidinii M 363 grown on methanol and glucose as control were investigated using electron microscopy, cytochemical and biochemical methods. An ultrastructural rearrangement of the polymers in the cell wall of yeasts cultivated on methanol in comparison to those cultivated on glucose was established. The morphological changes correlate to the quantitative changes in the polysaccharide constituents of the cell wall. The forming and the role of thiosemihydrocarbazide (TSHC) — negative zones in theCandida boidinii cell wall cultivated on methanol media are discussed.     

Incorporation of galactose from UDP-galactose into microsomal and golgi membranes of rat liver

Rough and smooth microsomes and Golgi membranes were incubated with UDP[¹⁴C]galactose and the incorporation of radioactivity into the lipid extract and into endogenous protein acceptors were measured. Antagonistic pyrophosphatases were inhibited with ATP and interference from β-galactosidase activity was greatly decreased by carrying out the incubation at pH 7.8. After incubation the particles were centrifuged to remove free oligosaccharide residues. Radioactivity was found in the lipid extract from Golgi membranes but not from rough and smooth microsomes. This radioactivity, however, was not associated with dolichol or retinyl phosphates. The incorporation of radioactivity into proteins of the Golgi fraction was more than double than that of the microsomal fractions. In addition, the transferases in these two types of particles exhibited different properties. Trypsin treatment of intact rough microsomal vesicles, smooth vesicles and Golgi membranes removed about 5, 15 and 50%, respectively, of newly incorporated protein-bound galactose, indicating that the proportion of the newly galactosylated proteins, which are localized at the cytoplasmic surface of the membrane, is lowest in rough microsomes, intermediate in smooth, and highest in Golgi membranes.     

Metabolism of [14C]glucose by regenerating spheroplasts of Candida albicans

Spheroplasts of Candida albicans were regenerated in [14C]glucose and buffered magnesium sulphate (0.1 M-Tris/HCl; 0.5 M-MgSO4, pH 7.2) at 35 degrees C. Uptake of glucose by spheroplasts was faster than that by intact yeast cells. After 6 h, 65% of the glucose taken up by the yeast appeared as CO2 and 30% was incorporated into the cellular material. With spheroplasts, 55% of the glucose taken up was expired as CO2, 25% was excreted into the medium as other metabolites and 20% was incorporated into the cells. The regenerating spheroplasts excreted 14C-labelled carbohydrates into the medium which were fractionated on a Sephadex G-15 column. Acid hydrolysis of the low molecular-weight fraction yielded the following sugars: mannose (75.7%), fucose (3.8%), arabinose (3%), galactose (2.1%) and an unidentified monosaccharide (14%). Spheroplasts did not incorporate mannoprotein into the regenerated wall. The wall carbohydrate from regenerated spheroplasts was fractionated on the basis of solubility in sodium hydroxide. The alkali-insoluble fraction was analysed by sequential enzyme hydrolysis; 40% of the incorporated counts were associated with beta (1----3)-linked glucan and 50% with a mixed glucan comprising beta (1----3)- and beta (1----6)-linkages and chitin.     

Studies of the cell walls of Schizophyllum commune

Mechanically isolated cell wall materials of eight strains of Schizophyllum commune were studied by chemical and enzymatic procedures. Isolated wall material of each strain was separated by chemical methods into three fractions: A (cold alkali-soluble, , amorphous), B (warm alkali-soluble, amorphous), and C (alkali-insoluble, retaining appearance of hyphal fragments). Chemical tests indicated the presence of chitin in Fraction C and the absence of cellulose, lignin and pectic substances from all fractions. Analyses of acid hydrolysates indicated the presence of glucose in Fractions A, B and C, of hexosamine in Fraction C and the absence of galactose, mannose, 6-deoxyhexoses, xylose and other pentoses from all fractions. Unfractionated material, Fraction A and Fraction B were slightly attacked by commercial cellulase whereas Fraction C was heavily attacked. Commercial chitinase by itself did not attack Fraction C or unfractionated material to a significant extent. In the presence of cellulase, it was active upon Fraction C. Qualitative differences in cell wall composition between strains were not detected; however, quantitative differences were observed in the proportion of Fraction A and Fraction C as well as in the amount of the various breakdown products in certain strains. It is visualized that the cell wall of this fungus consists of a core of chitin covered by or intermeshed with glucose-containing polymers.     

Effects of ethanol and diabetes on galactose oxidative metabolism and elimination in rats.

Blood galactose clearance after an intravenous galactose load has been widely used for years as an index of liver function. We developed a noninvasive [13C]galactose breath test, which explores galactose oxidative metabolism; this test is well correlated with liver fibrosis in patients with chronic viral hepatitis. The goal of this study was to evaluate the influence of nonhepatic factors such as diabetes and ethanol on whole-body galactose clearance (measured as the serum galactose elimination capacity test) and oxidative metabolism (measured as the [13C]galactose-induced breath 13CO2 production) in rats. Acute ethanol administration induced a significant decrease of galactose clearance and 13CO2 production. There was a significant correlation between the amount of ethanol given and the inhibition of galactose metabolism (R2 = 0.72, p < 0.0001). In streptozotocin-induced diabetic rats, the [13C]galactose-induced breath 13CO2 production was significantly reduced (p < 0.0001) and normalized by insulin treatment. However, diabetes did not decrease whole-body galactose clearance, indicating an isotopic dilution of [13C]glucose produced from [13C]galactose metabolism into the enlarged glucose pool. These results must be taken into account when using the [13C]galactose breath test as a quantitative liver function test.     

Effects of erythrocyte lipid and of glucose and galactose concentration on transport of the sugars across a water-butanol interface

A property of sugar transport into the human erythrocyte is that a sugar with a high affinity for the hypothetical "carrier" will enter the cell at low concentration more rapidly than a sugar with lower affinity for carrier. At high concentration the sequence will be reversed. This behavior is exemplified by glucose, which enters erythrocytes faster than galactose at 0.015 m and slower than galactose at 1.3 m. A physicochemical model with the same properties has been found: layers of butanol and water with erythrocyte lipid at the interface. With total lipid from the human erythrocyte incorporated into the model, glucose at low concentration enters the oil phase faster than galactose and at high concentration galactose enters more rapidly. In the absence of lipid, glucose flux exceeds galactose flux at all concentrations. The hypothetical carrier molecule has not been identified.