Structure of a lipid intermediate in cell wall peptidoglycan synthesis: a derivative of a C55 isoprenoid alcohol

Bacterial glycolipids

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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.

Mechanism of polymerization of the Salmonella O-antigen: utilization of lipid-linked intermediates

Cell envelope fractions from Salmonella can utilize exogenous lipid-linked intermediates for the synthesis of polymeric O-antigen. We describe a method for preparing aqueous suspensions of lipid intermediates and show that freezing and thawing of cell envelope-lipid intermediate mixtures is required for efficient synthesis. The lipid intermediates move freely in the hydrophobic environment of the membrane.

Iodinated vancomycin and mucopeptide biosynthesis by cell-free preparations from Micrococcus lysodeikticus

A particulate preparation from Micrococcus lysodeikticus was used to synthesize cell-wall mucopeptide. Radioactive iodinated vancomycin became attached to the preparation simultaneously with a complete inhibition of mucopeptide synthesis. After mucopeptide synthesis had occurred in the absence of antibiotic, the preparation took up more vancomycin, suggesting that new binding sites terminating in acyl-d-alanyl-d-alanine had been produced. The mucopeptide product was divided into a soluble and an insoluble portion, both sensitive to lysozyme. The soluble portion did not combine with vancomycin and hence had presumably lost its terminal d-alanine residues, either by transpeptidation or because of carboxy-peptidase action. The synthesis of both portions was unaffected by the presence of penicillin, but the insoluble part showed increased affinity for vancomycin, thus indicating that penicillin had caused conservation of d-alanyl-d-alanine termini.

The characterization of undecaprenol of Lactobacillus plantarum

Evidence for the presence of undecaprenol in the unsaponifiable lipid of Lactobacillus plantarum (N.C.I.B. 6376) is presented. Characterization of the compound was based mainly on mass, i.r. and n.m.r. spectrometry. The prenol was isolated at a concentration of 40mug/g wet wt. of bacteria and contained over 90% (1.0-5.4% of the dose) of the (14)C present in the unsaponifiable lipid after incubation of the bacteria with [2-(14)C]mevalonate. N.m.r. spectrometry indicated the presence of two internal trans-, one alpha-cis- and seven internal cis-isoprene residues per molecule. The (3)H/(14)C ratios of the prenol after incubation of the bacteria with [2-(14)C,(4R)-4-(3)H(1)]- and [2-(14)C,(4S)-4-(3)H(1)]-mevalonate were in agreement with this stereochemistry. There was no evidence of saturated isoprene residues in the molecule. The undecaprenol appeared to be accompanied by much smaller quantities of decaprenol and nonaprenol.

Mevalonate metabolism in supernatant fractions of lysates of Lactobacillus plantarum

The supernatant fractions of lysates of Lactobacillus plantarum metabolize mevalonate into lipids. Adenosine triphosphate and uridine, as well as related compounds, and reduced nicotinamide adenine dinucleotide phosphate or reduced nicotinamide adenine dinucleotide stimulate this process. To obtain very active supernatant fractions, the method of lysis is modified to include polyamines during lysozyme treatment of cells and subsequent shocking with citrate buffer.

Dolichol monophosphate glucose: an intermediate in glucose transfer in liver

The microsomal fraction of liver has been found to catalyze glucose transfer from UDPG to a lipid acceptor which appears to be identical to the compound obtained by chemical phosphorylation of dolichol. The substance formed (dolichol monophosphate glucose) is acid labile and yields 1,6-anhydroglucosan by alkaline treatment. It can be used as substrate by the enzyme system yielding a glucoprotein which is subsequently hydrolyzed to glucose.

The preparation of iodinated vancomycin and its distribution in bacteria treated with the antibiotic

Vancomycin was radioactively labelled by iodination with (125)I.Iodinated vancomycin was only a little less potent as an antibiotic than vancomycin itself. It was shown, both by chromatography and differential absorption measurements, to combine with acyl-d-alanyl-d-alanine residues. Radioactive vancomycin was used to follow the fate of the antibiotic in bacteria that had been subjected to the least concentration required to inhibit growth. Most of the radioactivity was in the cell walls, although some was found in the membrane fraction. The latter proportion increased during longer incubations with the antibiotic. Pre-formed protoplasts adsorbed very little vancomycin. Mg(2+) removed labelled vancomycin from the mucopeptide of Bacillus licheniformis, but had little effect on the antibiotic adsorbed on Micrococcus lysodeikticus, either in vivo or on previously isolated cell walls. Specific peptide was shown to compete with cell walls for vancomycin and it also extracted from cell-wall samples the labelled compound that had been adsorbed on M. lysodeikticus living cells.

A lipid intermediate in the synthesis of a poly-(N-acetylglucosamine 1-phosphate) from the wall of Staphylococcus lactis N.C.T.C. 2102

1. The enzymic synthesis of the wall polymer poly-(N-acetylglucosamine 1-phosphate) in Staphylococcus lactis N.C.T.C. 2102 was studied by using UDP-[acetyl-(14)C]N-acetylglucosamine and the corresponding nucleotide containing (32)P. 2. Labelled material was extracted from the particulate enzyme preparation with butan-1-ol. Pulse-labelling experiments indicated that this material contained an intermediate in the biosynthesis. 3. The lipid intermediate was partially purified, and chemical and enzymic degradation showed that it was composed of N-acetylglucosamine 1-pyrophosphate in labile ester linkage to an organic-soluble alcohol, possibly a polyisoprenoid alcohol. The methanolysis of sugar 1-pyrophosphate derivatives, including nucleoside diphosphate sugars, is discussed in relation to degradation products obtained from the lipid. 4. The lipids from the particulate enzyme preparation probably contained another compound in which N-acetylglucosamine 1-phosphate is attached to an organic-soluble alcohol; this may participate in the biosynthesis of another polysaccharide. 5. The function of the lipid intermediate in polymer biosynthesis is discussed.

Biosynthesis of cell wall lipopolysaccharide in mutants of Salmonella. V. A mutant of Salmonella typhimurium defective in the synthesis of cytidine diphosphoabequose

A mutant of Salmonella typhimurium LT2 was found to be unable to convert cytidine diphospho-4-keto-6-deoxy-d-glucose into cytidine diphosphoabequose. The mutation maps in the rfb gene cluster, which is known to be involved in the biosynthesis of the peripheral, "O side-chain" portion of cell wall lipopolysaccharide. In spite of the fact that, in the O side chains, abequose is not a part of the main chain but occurs as short branches, the mutant appears to be unable to polymerize oligosaccharide "repeat units" into long O side chains. The following evidence indicates that this failure is the result of the absence of cytidine diphosphoabequose rather than that of a superimposed second mutation in other genes of the rfb cluster. (i) The mutant does not behave like a multisite mutant in genetic crosses, and it gives rise, at a high frequency, to "revertants" where the ability to synthesize cytidine diphosphoabequose and the ability to synthesize normal lipopolysaccharide with O side chains are both restored. (ii) The mutant strain has normal levels of activity of all of the other enzymes known to be involved in O side-chain synthesis, except that the levels of several enzymes were lowered by about 30% owing to the polarity effect of the mutation. That the lowering of these enzymes is not responsible for the failure of the mutant to synthesize O side chains is clear from the fact that there were revertants which had regained some ability to synthesize abequose but still had lowered levels of these other enzymes, and that this type of revertant produced lipopolysaccharide with considerable amounts of O side chains.

The mechanism of biosynthesis and direction of chain extension of a poly-(N-acetylglucosamine 1-phosphate) from the walls of Staphylococcus lactis N.C.T.C. 2102

1. The synthesis of a polymer of N-acetylglucosamine 1-phosphate, occurring in the walls of Staphylococcus lactis N.C.T.C. 2102, was examined by using cell-free enzyme preparations. The enzyme system was particulate, and probably represents fragmented cytoplasmic membrane. 2. Uridine diphosphate N-acetylglucosamine was the only substrate required for polymer synthesis and labelled substrate was used to show that N-acetylglucosamine 1-phosphate is transferred as an intact unit from substrate to polymer. 3. The properties of the enzyme system were studied. A high concentration of Mg(2+) or Mn(2+) was required for optimum activity, and the pH optimum was about 8.5. 4. End-group analysis during synthesis in vitro showed that newly formed chains contain up to about 15 repeating units. Pulse-labelling indicated that chain extension occurs by transfer from the nucleotide to the ;sugar-end' of the chain, i.e. to the end that is not attached to peptidoglycan in the wall.

Expression and localization of Escherichia coli alkaline phosphatase synthesized in Salmonella typhimurium cytoplasm

The Escherichia coli structural gene for alkaline phosphatase was inserted into Salmonella typhimurium by episomal transfer in order to determine whether this enzyme would continue to be localized to the periplasmic space of the bacterium even though it was formed in a cell that does not synthesize alkaline phosphatase. The S. typhimurium heterogenote synthesized alkaline phosphatase under conditions identical to that observed with E. coli. This enzyme appeared to be identical to that synthesized by E. coli, and was quantitatively released from the bacterial cell by spheroplast formation with lysozyme. These results showed that localization is not a property unique to the E. coli cell and suggested that, in E. coli, enzyme location is related to the structure of the protein. Formation of alkaline phosphatase in the S. typhimurium heterogenote was repressed in cells growing in a medium with excess inorganic phosphate, even though only one of the three regulatory genes for this enzyme is on the episome. Thus, S. typhimurium can supply the products of the other two regulatory genes essential for repression even though this bacterium seems to lack the structural gene for alkaline phosphatase.

The characterization and distribution of hexahydropolyprenyl esters in cultures of Aspergillus fumigatus Fresenius

The total mycelial lipid of Aspergillus fumigatus was analysed and over half of its hexahydropolyprenol was shown to be esterified with fatty acids. Comparison of the fatty acid content of the prenyl esters with the sterol ester and the total lipid indicated a marked predominance of saturated fatty acids in the polyprenyl esters. The predominant acids esterified to the prenols were palmitic acid, linoleic acid, oleic acid, lignoceric acid, stearic acid and palmitoleic acid. Most of the unesterified polyprenol was found in the mitochondrial fraction, but the esterified prenol was equally distributed throughout the cell fractions. This distribution was unlike that found for ergosteryl ester in the same tissue.

Reversal of the vancomycin inhibition of peptidoglycan synthesis by cell walls

Addition of cell walls to the peptidoglycan synthetase-acceptor system containing vancomycin (50 mug/ml) prevented the inhibition by the antibiotic. In addition, the inhibition of incorporation of [(14)C]muramyl-pentapeptide into peptidoglycan in the presence of vancomycin was reversed by the addition of cell walls to the assay mixture at 60 min. Cell walls previously saturated with vancomycin lost their ability to reverse the inhibition by the antibiotic. The inhibition of peptidoglycan synthesis by ristocetin was partially reversed by the addition of cell walls. The initial stage in peptidoglycan synthesis is catalyzed by phospho-N-acetyl(NAc)muramyl-pentapeptide translocase (uridine 5'-phosphate) according to the reaction: UDP-NAc-muramyl-pentapeptide + acceptor right arrow over left arrow acceptor-phospho-NAc-muramyl-pentapeptide + UMP where acceptor is C(55)-isoprenoid alcohol phosphate. Vancomycin stimulates the transfer of phospho-NAc-muramyl-pentapeptide to the acceptor, and the addition of cell walls to this assay mixture prevented the stimulation of transfer. In addition to the transfer reaction, the enzyme catalyzes the exchange of [(3)H]uridine monophosphate (UMP) with UDP-NAc-muramyl-pentapeptide. The exchange reaction is effectively inhibited by vancomycin. For example, 60 mug of vancomycin per ml inhibited the rate of exchange by 50%. Addition of cell walls restored the exchange of UMP with the UMP moiety of UDP-NAc-muramyl-pentapeptide. Thus, cell walls appeared to have a higher affinity for vancomycin than did either the peptidoglycan synthetase-acceptor system or phospho-NAc-muramyl-pentapeptide translocase. These results provide support for the proposal made by Best and Durham that the effective binding of vancomycin to the cell wall could result in the inhibition of transfer of membrane-associated peptidoglycan chains to the growing wall.

Biosynthesis of the O antigen from Citrobacter 139

The biosynthesis of the O antigen of Citrobacter 139 (Escherichia coli 3 Zurich 4,5,12:z(20)) was shown to proceed through a series of lipid-linked intermediates, similar to those involved in O-antigen synthesis in Salmonella. Galactose was the first sugar incorporated, followed by rhamnose and mannose. Abequose was incorporated from cytidine diphosphate (CDP)-abequose only when all three of the other nucleotide sugars (uridine diphosphate galactose, guanosine diphosphate mannose, and thymidine diphosphate rhamnose) were present. Rhamnosyl-galactosyl 1-phosphate and mannosyl-rhamnosyl-galactosyl 1-phosphate were identified as the products of mild alkaline hydrolysis of the lipid-linked intermediates.

The glycolipids of Lactobacillus casei A.T.C.C. 7469

1. The lipids were extracted from Lactobacillus casei A.T.C.C. 7469 with chloroform-methanol mixtures. The glycolipids were obtained by chromatography on silicic acid and DEAE-cellulose (acetate form). 2. Hydrolysis of the glycolipids with alkali gave two glycerol glycosides and a mixture of fatty acids. 3. The glycosides were separated and their structures elucidated. The major component was O-alpha-d-galactopyranosyl-(1-->2)-O-alpha-d-glucopyranosyl-(1-->1)-glycerol and the minor component O-alpha-d-glucopyranosyl-(1-->6)-O-alpha-d-galactopyranosyl-(1-->2)-O-alpha-d-glucopyranosyl-(1-->1)-glycerol. 4. Analysis of the fatty acids by gas-liquid chromatography showed that they were predominantly palmitic acid, octadecenoic acid and lactobacillic acid.

Lipids of Salmonella typhimurium and Escherichia coli: structure and metabolism

The nature and quantity of the phospholipids of Salmonella typhimurium and Escherichia coli K-12 have been examined. The main classes of phospholipids, phosphatidylethanolamine, phosphatidylglycerol, and cardiolipin have been completely characterized. Four minor compounds have been detected: phosphatidylserine, phosphatidic acid, and two partially characterized lipids. The phospholipid composition of the two organisms is quite similar, the only difference is the absence of one of the minor components and a decreased level of all components in E. coli. A study of the turnover of the phosphate in the phospholipids demonstrated no turnover in phosphatidylethanolamine, a slow turnover in phosphatidylglycerol, and a slow turnover in cardiolipin with, possibly, a transfer of phosphate from phosphatidylglycerol to cardiolipin. The amino acid phenylalanine is shown to become incorporated intact into lipidic compounds which have been partially characterized. Methods for the isolation and separation of lipids have been examined for their utility with these bacteria.

Direction of chain growth in polysaccharide synthesis

The biosynthesis of a bacterial polysaccharide-the surface O-antigen of Salmonella newington-differs in several respects from the more classical example of glycogen synthesis. Sugars are not transferred directly to the antigen from sugar nucleotide precursors but are transferred first into lipid-linked oligosaccharides. Growth of the polysaccharide chain then occurs by assembly of these lipid-linked precursors at the reducing end of the polymer rather than at its nonreducing end as in glycogen. This method of assembly, in which nascent chains are transferred to the next subunit, is analogous to the growth of proteins or fatty acids. It seems possible that these differences reflect the more complex requirements of a surface polysaccharide synthesized by membrane-bound enzymes. If this is the case, then several other polysaccharide systems may be synthesized by comparable mechanisms.