Location, synthesis and function of glycolipids and polyglycerolphosphate lipoteichoic acid in Gram-positive bacteria of the phylum Firmicutes

Lipoteichoic acid (LTA) is a zwitterionic polymer found in the cell wall of many Gram-positive bacteria. A widespread and one of the best-studied forms of LTA consists of a polyglycerolphosphate (PGP) chain that is tethered to the membrane via a glycolipid anchor. In this review, we will summarize our current understanding of the enzymes involved in glycolipid and PGP backbone synthesis in a variety of different Gram-positive bacteria. The recent identification of key LTA synthesis proteins allowed the construction and analysis of mutant strains with defined defects in glycolipid or backbone synthesis. Using these strains, new information on the functions of LTA for bacterial growth, physiology and during developmental processes was gained and will be discussed. Furthermore, we will reintroduce the idea that LTA remains in close proximity to the bacterial membrane for its function during bacterial growth rather than as a surface-exposed structure.     

Two-enzyme systems for glycolipid and polyglycerolphosphate lipoteichoic acid synthesis in Listeria monocytogenes

Lipoteichoic acid (LTA) is an important cell wall polymer in Gram-positive bacteria and often consists a polyglycerolphosphate backbone chain that is linked to the membrane by a glycolipid. In Listeria monocytogenes this glycolipid is Gal-Glc-DAG or Gal-Ptd-6Glc-DAG. Using a bioinformatics approach, we have identified L. monocytogenes genes predicted to be involved in glycolipid ( lmo2555 and lmo2554 ) and LTA backbone ( lmo0644 and lmo0927 ) synthesis. LTA and glycolipid analysis of wild-type and mutant strains confirmed the function of Lmo2555 and Lmo2554 as glycosyltransferases required for the formation of Glc-DAG and Gal-Glc-DAG. Deletion of a third gene, lmo2553 , located in the same operon resulted in the production of LTA with an altered structure. lmo0927 and lmo0644 encode proteins with high similarity to the staphylococcal LTA synthase LtaS, which is responsible for polyglycerolphosphate backbone synthesis. We show that both proteins are involved in LTA synthesis. Our data support a model whereby Lmo0644 acts as an LTA primase LtaP and transfers the initial glycerolphosphate onto the glycolipid anchor, and Lmo0927 functions as LTA synthase LtaS, which extends the glycerolphosphate backbone chain. Inactivation of LtaS leads to severe growth and cell division defects, underscoring the pivotal role of LTA in this Gram-positive pathogen.     

Characterization of lipoteichoic acid structures from three probiotic Bacillus strains: involvement of d-alanine in their biological activity

Probiotics represent a potential strategy to influence the host’s immune system thereby modulating immune response. Lipoteichoic Acid (LTA) is a major immune-stimulating component of Gram-positive cell envelopes. This amphiphilic polymer, anchored in the cytoplasmic membrane by means of its glycolipid component, typically consists of a poly (glycerol-phosphate) chain with d-alanine and/or glycosyl substitutions. LTA is known to stimulate macrophages in vitro, leading to secretion of inflammatory mediators such as Nitric Oxide (NO). This study investigates the structure–activity relationship of purified LTA from three probiotic Bacillus strains (Bacillus cereus CH, Bacillus subtilis CU1 and Bacillus clausii O/C). LTAs were extracted from bacterial cultures and purified. Chemical modification by means of hydrolysis at pH 8.5 was performed to remove d-alanine. The molecular structure of native and modified LTAs was determined by ¹H NMR and GC–MS, and their inflammatory potential investigated by measuring NO production by RAW 264.7 macrophages. Structural analysis revealed several differences between the newly characterized LTAs, mainly relating to their d-alanylation rates and poly (glycerol-phosphate) chain length. We observed induction of NO production by LTAs from B. subtilis and B. clausii, whereas weaker NO production was observed with B. cereus. LTA dealanylation abrogated NO production independently of the glycolipid component, suggesting that immunomodulatory potential depends on d-alanine substitutions. d-alanine may control the spatial configuration of LTAs and their recognition by cell receptors. Knowledge of molecular mechanisms behind the immunomodulatory abilities of probiotics is essential to optimize their use.     

Synthesis of the lipoteichoic acid of the Streptococcus species DSM 8747

The lipoteichoic acid (LTA) of the Streptococcus species DSM 8747 consists of a β-d-galactofuranosyl diacylglycerol moiety (with different acyl groups) that is linked via 6-O to a poly(glycerophosphate) backbone; about 30% of the glycerophosphate moieties carry at 2-O hydrolytically labile d-alanyl residues. As typical LTA for this array of compounds LTA 1a was synthesized. To this end, from d-galactose the required galactofuranosyl building block 5 was obtained. The anomeric stereocontrol in the glycosylation step with 1,2-O-cyclohexylidene-sn-glycerol (4) was based on anchimeric assistance, thus finally leading to the unprotected core glycolipid 16. Regioselective protection and deprotection procedures permitted the defined attachment of the pentameric glycerophosphate 3 to the 6-hydroxy group of the galactose residue. Introduction of four d-alanyl residues led after global deprotection and purification to target molecule 1a possessing on average about two d-alanyl residues at 2-O of the pentameric glycerophosphate backbone, thus being in close accordance with the structure of the natural material.     

Structural analysis by mass spectrometry and NMR spectroscopy of the glycolipid sulfate from Halobacterium salinarium and a note on its possible function

The major glycolipid sulfate of the extreme halophile Halobacterium salinarium was isolated and characterised mainly by mass spectrometry and NMR spectroscopy. The mass spectrum of the permethylated, desulfated and trimethylsilylated derivative showed the molecule to be a trihexosyl glycerol C₂₀-diether with the sulfate group on the terminal hexose. A 3-position of the sulfate was indicated by the mass spectrum obtained after acetylation and trimethylsilylation (solvolysis of sulfate and replacement by a trimethylsilyl group). The NMR spectrum of the desulfated permethylated glycolipid gave conclusive evidence for the presence of one β and two α anomeric protons. With the knowledge of degradation data it was possible to assign the β signal to galactose (terminal hexone), and the α signals to glucose and mannose. These data together make it likely that the glycolipid sulfate is identical in structure with the glycolipid from Halobacterium cutirubrum characterised previously (M. Kates and P.W. Deroo, J. Lipid Res., 14 (1973) 438).On the basis of a suggested function of cerebroside sulfate of animal origin (identical polar end with the bacterial glycolipid: β-galactopyranose-3-sulfate) and the present knowledge of ion transport in Halobacteria, it is proposed that the bacterial glycolipid may function as a selective K⁺ receptor for the K⁺ transport from a high-Na⁺ and low-K⁺ outside medium.     

A Staphylococcus aureus ypfP mutant with strongly reduced lipoteichoic acid (LTA) content: LTA governs bacterial surface properties and autolysin activity

Many Gram-positive bacteria produce lipoteichoic acid (LTA) polymers whose physiological roles have remained a matter of debate because of the lack of LTA-deficient mutants. The ypfP gene responsible for biosynthesis of a glycolipid found in LTA was deleted in Staphylococcus aureus SA113, causing 87% reduction of the LTA content. Mass spectrometry and nuclear magnetic resonance spectroscopy revealed that the mutant LTA contained a diacylglycerol anchor instead of the glycolipid, whereas the remaining part was similar to the wild-type polymer except that it was shorter. The LTA mutant strain revealed no major changes in patterns of cell wall proteins or autolytic enzymes compared with the parental strain indicating that LTA may be less important in S. aureus protein attachment than previously thought. However, the autolytic activity of the mutant was strongly reduced demonstrating a role of LTA in controlling autolysin activity. Moreover, the hydrophobicity of the LTA mutant was altered and its ability to form biofilms on plastic was completely abrogated indicating a profound impact of LTA on physicochemical properties of bacterial surfaces. We propose to consider LTA and its biosynthetic enzymes as targets for new antibiofilm strategies.     

Deep-sea Rhodococcus sp. BS-15, Lacking the Phytopathogenic fas Genes,Produces a Novel Glucotriose Lipid Biosurfactant

Glycolipid biosurfactant-producing bacteria were isolated from deep-sea sediment collected from the Okinawa Trough. Isolate BS15 produced the largest amount of the glycolipid, generating up to 6.31?±?1.15 g l^?1 after 4 days at 20 °C. Glucose was identified in the hydrolysate of the purified major component of the biosurfactant glycolipid. According to gas chromatography/mass spectrometry analysis, the hydrophobic moieties in the major component were hexadecanoate, octadecanoate, 3-hydroxyhexadecanoate, 2-hydroxyoctanoate, and succinate. The molecular weight of the purified major glycolipid was calculated to be 1,211, while ¹H and ¹³C nuclear magnetic resonance spectra confirmed that the major component consisted of 2 mol of α-glucoside and 1 mol of β-glucoside. The molecular structure was assigned as novel trisaccharide-type glycolipid biosurfactant, glucotriose lipids. The critical micelle concentration of the purified major glycolipid was 2.3?×?10^?6 M, with a surface tension of 29.5 mN m^?1. Phylogenetic analysis showed isolate BS15 was closely related to a Rhodococcus strains isolated from Antarctica, and to Rhodococcus fascians, a phytopathogen. PCR analysis showed that the fasA, fasB, fasC, fasD, fasE, and fasF genes, which are involved in phytohormone-like cytokinin production, were not present in the genome of BS15; however, analysis of a draft genome sequence of BS15 (5.5 Mb) identified regions with 31 %, 53 %, 46 %, 30 %, and 31 % DNA sequence identity to the fasA, fasB, fasC, and fasD genes, respectively.     

Glycosyl-phosphatidylinositols ofTrypanosoma congolense: Two Common Precursors but a New Protein-anchor

The parasitic protozoanTrypanosoma congolenseexhibits a dense surface coat which is pivotal for immunoevasion of the parasite. This dense surface coat is made of a single protein species, the variant surface glycoprotein, which is present in a high copy number. The protein is anchored to the plasma membrane by a glycosyl-phosphatidylinositol membrane anchor. A detailed study of the structure ofT. congolensestrain 423 (clone BENat 1.3) variant surface glycoprotein glycosyl-phosphatidylinositol membrane anchor was performed. Radioactively labelled core-glycan prepared by dephosphorylation, deamination and reduction was analysed by high- pH anion-exchange chromatography, size-exclusion and lectin affinity chromatography. Additionally the glycosyl-phosphatidylinositol mem brane anchor core-glycan was purified from a bulk preparation of variant surface glycoprotein and subjected to mass spectrometry and methylation analysis. Using these methods we could identify a novel galactose- β1,6-N-acetyl-glucosamine-β1,4-branch modifying the mannose adjacent to the glucosamine of the mannose-α1,2-mannose-α1,6-mannose-α1,4- glucosamine core-glycan of the variant surface glycoprotein glycosyl-phos phatidylinositol membrane anchor. Furthermore the biosynthetic pathway leading to this novel structure was investigated. Two putative glycosyl-phosphatidylinositol anchor precursors were identified having structures identical to the previously characterizedTrypanosoma brucei bruceiglycolipids P2 and P3 (also designated glycolipid A and C) consistent with a trimannosyl core and a dimyristoyl-glycerol. Both glycosyl-phosphatidylinositol anchor precursors ofT. congolensedo not possess the side-branch modification found on the mature protein membrane anchor, implying that the sugar side-chain is added to the anchor during its passage through the Golgi-apparatus.     

Formation of Molecular Complexes Between a Structurally Defined M Protein and Acylated or Deacylated Lipoteichoic Acid of Streptococcus pyogenes

The orientation of lipoteichoic acid (LTA) molecules on the surface of bacterial cells undoubtedly is determined by the ability of the LTA, during its transit through the cell wall, to bind via its polyglycerophosphate backbone or its glycolipid moieties to other constituents of the cytoplasmic membrane and the cell wall. We have investigated the possibility that LTA may become anchored to the cell surface by binding through its polyanionic backbone to positively charged regions of cell wall proteins. LTA was found to prevent the precipitation of partially purified HCl extracts of several strains of streptococci as well as a structurally defined streptococcal M protein molecule (pep M24) in 83% solutions of ethanol. The formation of complexes between LTA and M protein was demonstrated further by immunoelectrophoresis of pep M24 protein with increasing concentrations of radiolabeled LTA and by using antiserum against pep M24 to develop precipitin arcs. Pep M24 electrophoresed alone produced a single precipitin arc close to the origin. In contrast, when electrophoresed as a mixture with LTA or deacylated LTA, the M protein produced a second precipitin arc toward the anode coinciding with the area of migration of the radioactive LTA. Increasing concentrations of LTA or deacylated LTA shifted increasing amounts of the pep M24 antigen to the region of the second arc. Maleylation of M protein to block the positively charged free amino groups before mixing it with LTA prevented the formation of complexes. The complexes formed by the M protein with LTA, but not with deacylated LTA, showed the capacity to bind bovine serum albumin; LTA had been shown previously to bind to the fatty acid binding sites on bovine serum albumin. These results indicate that the LTA molecule is able to bind via its polyanionic backbone to positively charged residues of surface proteins of cells of S. pyogenes. The implications of such interaction as to the orientation of LTA molecules on the surface of cells of S. pyogenes are discussed.     

Multi-spectrometric analyses of lipoteichoic acids isolated from Lactobacillus plantarum

Lipoteichoic acid is a major cell wall virulence factor of gram-positive bacteria. LTAs from various bacteria have differential immunostimulatory potentials due to heterogeneity in their structures. Although recent studies have demonstrated that LTA isolated from Lactobacillus plantarum (pLTA) has anti-inflammatory properties and is less inflammatory than LTAs from pathogenic bacteria, little is known about the structure of pLTA. In this study, high-field NMR spectra of the pLTA were compared with those of LTA from pathogenic bacterium, Staphylococcus aureus (aLTA). The 2D NMR results demonstrated that pLTA possesses α-linked hexose sugar substituents on the poly-glycerophosphate backbone instead of N-acetylglucosamine substituents, and unsaturated fatty acids in its glycolipids. The sugar substituents were revealed as an approximately 29:1 molar ratio of the glucose to galactose by HPAEC-PAD analysis. MALDI-TOF/TOF MS analyses identified the presence of unsaturated fatty acids in the glycolipid moieties of pLTA. In addition, the glycolipid structure was found to be composed of trihexosyl-diacyl- and/or trihexosyl-triacyl-glycerol ceramide units by means of unique fragment ions of the glycolipids. These results enabled us to elucidate the pLTA structure, which is distinctively different from canonical LTA structure, and suggest that the unique immunological property of pLTA might be caused by the pLTA structure.     

A sensitive fluorigenic substrate for selective in vitro and in vivo assay of leukotriene A4 hydrolase activity

Leukotriene A4 hydrolase (LTA4H) is a bifunctional zinc-dependent metalloprotease bearing both an epoxide hydrolase, producing the pro-inflammatory LTB4 leukotriene, and an aminopeptidase activity, whose physiological relevance has long been ignored. Distinct substrates are commonly used for each activity, although none is completely satisfactory; LTA4, substrate for the hydrolase activity, is unstable and inactivates the enzyme, whereas aminoacids β-naphthylamide and para-nitroanilide, used as aminopeptidase substrates, are poor and nonselective. Based on the three-dimensional structure of LTA4H, we describe a new, specific, and high-affinity fluorigenic substrate, PL553 [l-(4-benzoyl)phenylalanyl-β-naphthylamide], with both in vitro and in vivo applications. PL553 possesses a catalytic efficiency (k_cat/K_m) of 3.8 ± 0.5 × 10⁴ M⁻¹ s⁻¹ using human recombinant LTA4H and a limit of detection and quantification of less than 1 to 2 ng. The PL553 assay was validated by measuring the inhibitory potency of known LTA4H inhibitors and used to characterize new specific amino-phosphinic inhibitors. The LTA4H inhibition measured with PL553 in mouse tissues, after intravenous administration of inhibitors, was also correlated with a reduction in LTB4 levels. This authenticates the assay as the first allowing the easy measurement of endogenous LTA4H activity and in vitro specific screening of new LTA4H inhibitors.     

Differential localization of LTA synthesis proteins and their interaction with the cell division machinery in Staphylococcus aureus

Lipoteichoic acid (LTA) is an important cell wall component of Gram‐positive bacteria. In Staphylococcus aureus it consists of a polyglycerolphosphate‐chain that is retained within the membrane via a glycolipid. Using an immunofluorescence approach, we show here that the LTA polymer is not surface exposed in S. aureus, as it can only be detected after digestion of the peptidoglycan layer. S. aureus mutants lacking LTA are enlarged and show aberrant positioning of septa, suggesting a link between LTA synthesis and the cell division process. Using a bacterial two‐hybrid approach, we show that the three key LTA synthesis proteins, YpfP and LtaA, involved in glycolipid production, and LtaS, required for LTA backbone synthesis, interact with one another. All three proteins also interacted with numerous cell division and peptidoglycan synthesis proteins, suggesting the formation of a multi‐enzyme complex and providing further evidence for the co‐ordination of these processes. When assessed by fluorescence microscopy, YpfP and LtaA fluorescent protein fusions localized to the membrane while the LtaS enzyme accumulated at the cell division site. These data support a model whereby LTA backbone synthesis proceeds in S. aureus at the division site in co‐ordination with cell division, while glycolipid synthesis takes place throughout the membrane.     

Biosynthesis of the glycolipid anchor in lipoteichoic acid of Staphylococcus aureus RN4220: role of YpfP, the diglucosyldiacylglycerol synthase

In Staphylococcus aureus RN4220, lipoteichoic acid (LTA) is anchored in the membrane by a diglucosyldiacylglycerol moiety. The gene (ypfP) which encodes diglucosyldiacylglycerol synthase was recently cloned from Bacillus subtilis and expressed in Escherichia coli (P. Jorasch, F. P. Wolter, U. Zahringer, and E. Heinz, Mol. Microbiol. 29:419-430, 1998). To define the role of ypfP in this strain of S. aureus, a fragment of ypfP truncated from both ends was cloned into the thermosensitive replicon pVE6007 and used to inactivate ypfP. Chloramphenicol-resistant (ypfP::cat) clones did not synthesize the glycolipids monoglucosyldiacylglycerol and diglucosyldiacylglycerol. Thus, YpfP would appear to be the only diglucosyldiacylglycerol synthase in S. aureus providing glycolipid for LTA assembly. In LTA from the mutant, the glycolipid anchor is replaced by diacylglycerol. Although the doubling time of the mutant was identical to that of the wild type in Luria-Bertani (LB) medium, growth of the mutant in LB medium containing 1% glycine was not observed. This inhibition was antagonized by either L- or D-alanine. Moreover, viability of the mutant at 37 degrees C in 0.05 M phosphate (pH 7.2)-saline for 12 h was reduced to <0.1%. Addition of 0.1% D-glucose to the phosphate-saline ensured viability under these conditions. The autolysis of the ypfP::cat mutant in the presence of 0.05% Triton X-100 was 1.8-fold faster than that of the parental strain. Electron microscopy of the mutant revealed not only a small increase in cell size but also the presence of pleomorphic cells. Each of these phenotypes may be correlated with either (or both) a deficiency of free glycolipid in the membrane or the replacement of the usual glycolipid anchor of LTA with diacylglycerol.     

Meiothermus rufus sp. nov., a new slightly thermophilic red-pigmented species and emended description of the genus Meiothermus

Four red-pigmented isolates, with optimum growth temperatures of approximately 55–60 °C and an optimum pH for growth between 7.5 and 8.5, were recovered from hot springs in Central France. Phylogenetic analysis of the 16S rRNA gene sequences showed that these organisms represented a new species of the genus Meiothermus. The new isolates could be distinguished from other strains of the species of the genus Meiothermus primarily by the glycolipid profile and fatty acid composition because these organisms lacked the hydroxy fatty acids and the glycolipid variant GL-1a found in all other isolates of the species of Meiothermus examined. On the basis of the results presented here we propose the name Meiothermus rufus for the new species, which is represented by strains CAL-4^T (=DSM 22234^T=LMG 24878^T) and CAL-12 (=DSM 22235=LMG 24879). We also propose emending the genus Meiothermus to include strains that have only one glycolipid instead of two glycolipid variants.     

In Vitro Analysis of the Staphylococcus aureus Lipoteichoic Acid Synthase Enzyme Using Fluorescently Labeled Lipids

Lipoteichoic acid (LTA) is an important cell wall component of Gram-positive bacteria. The key enzyme responsible for polyglycerolphosphate lipoteichoic acid synthesis in the Gram-positive pathogen Staphylococcus aureus is the membrane-embedded lipoteichoic acid synthase enzyme, LtaS. It is presumed that LtaS hydrolyzes the glycerolphosphate head group of the membrane lipid phosphatidylglycerol (PG) and catalyzes the formation of the polyglycerolphosphate LTA backbone chain. Here we describe an in vitro assay for this new class of enzyme using PG with a fluorescently labeled fatty acid chain (NBD-PG) as the substrate and the recombinant soluble C-terminal enzymatic domain of LtaS (eLtaS). Thin-layer chromatography and mass spectrometry analysis of the lipid reaction products revealed that eLtaS is sufficient to cleave the glycerolphosphate head group from NBD-PG, resulting in the formation of NBD-diacylglycerol. An excess of soluble glycerolphosphate could not compete with the hydrolysis of the fluorescently labeled PG lipid substrate, in contrast to the addition of unlabeled PG. This indicates that the enzyme recognizes and binds other parts of the lipid substrate, besides the glycerolphosphate head group. Furthermore, eLtaS activity was Mn²⁺ ion dependent; Mg²⁺ and Ca²⁺ supported only weak enzyme activity. Addition of Zn²⁺ or EDTA inhibited enzyme activity even in the presence of Mn²⁺. The pH optimum of the enzyme was 6.5, characteristic for an enzyme that functions extracellularly. Lastly, we show that the in vitro assay can be used to study the enzyme activities of other members of the lipoteichoic acid synthase enzyme family.Lipoteichoic acid (LTA) is a crucial component of the cell wall envelope in Gram-positive bacteria. Diverse functions have been ascribed to LTA, including regulation of the activity of hydrolytic enzymes (4), an essential role in divalent cation homeostasis (2, 26, 37), and retention of noncovalently attached proteins within the cell wall envelope (20, 41). In addition, functions of LTA in host-pathogen interactions have been reported (44). d-Alanine modifications on LTA protect bacteria from killing by cationic antimicrobial peptides (36, 43) and are critical during the infection and colonization processes (1, 5, 10). On the other hand, LTA may also play a positive role for the host in wound healing, by preventing excessive inflammation (25).In the Gram-positive bacterial pathogen Staphylococcus aureus and in many other bacteria belonging to the Firmicutes, including Bacillus, Listeria, Streptococcus, Enterococcus, and Lactococcus spp., LTA is composed of a linear 1,3-linked polyglycerolphosphate backbone chain that is tethered via a glycolipid anchor to the bacterial membrane (6, 9). Recently, the staphylococcal protein LtaS was identified and shown to be responsible for polyglycerolphosphate LTA synthesis in vivo (14). An S. aureus strain depleted of LtaS is unable to synthesize LTA and shows severe growth and morphological defects (14); an S. aureus ltaS deletion strain is viable at 30°C only in a growth medium containing at least 1% NaCl or at higher temperatures at high salt (7.5%) or high sucrose (40%) concentrations (35). Taken together, these findings provide further evidence for the importance of this abundant cell envelope component for normal cell morphology and physiology.Pulse-chase experiments have provided strong biochemical evidence that the glycerolphosphate subunits of LTA are derived from the head group of the membrane lipid phosphatidylglycerol (PG) (7, 8, 12). A rapid and almost complete turnover of the nonacylated glycerolphosphate group of PG into LTA is observed in S. aureus and other Gram-positive bacteria that synthesize polyglycerolphosphate LTA (23, 24). It is assumed that the LtaS enzyme cleaves the head group of PG and uses this glycerolphosphate subunit to polymerize the LTA backbone chain.One or more LtaS-like enzymes are encoded in the genomes of Gram-positive bacteria that synthesize polyglycerolphosphate LTA (14). S. aureus LtaS and all other members of this enzyme family are predicted to contain five N-terminal transmembrane helices followed by an extracellular C-terminal enzymatic domain (eLtaS) (14, 29). The LtaS enzyme is processed in S. aureus, and the eLtaS domain is released into the culture supernatant as well as partially retained within the cell wall envelope (11, 29, 45). The crystal structure of the S. aureus eLtaS domain, alone and in a complex with soluble glycerolphosphate and the soluble domain of the Bacillus subtilis LtaS (LtaS_Bs) enzyme (YflE), identified a threonine as the catalytic residue. This is based on the location of the glycerolphosphate head group in the active site for S. aureus LtaS and on threonine phosphorylation in the B. subtilis enzyme structure (29, 37). Replacement of this threonine residue with an alanine renders the S. aureus enzyme inactive and unable to synthesize LTA in vivo (29). In addition, a Mn²⁺ ion was detected in the active center of the S. aureus LtaS structure, while the B. subtilis enzyme contained a Mg²⁺ ion.To provide insight into the enzymatic activity of the S. aureus lipoteichoic acid synthase enzyme, we developed an in vitro assay for this enzyme using purified recombinant eLtaS and fluorescently labeled PG as a substrate. Using thin-layer chromatography (TLC) and mass spectrometry analysis of the lipid reaction products, we show that eLtaS protein is sufficient to cleave the glycerolphosphate head group from NBD-PG, resulting in the formation of NBD-diacylglycerol (NBD-DAG). Furthermore, we provide experimental evidence that LtaS requires Mn²⁺ for enzyme activity, while Zn²⁺ inhibits enzyme function. Our results suggest that LtaS has a narrow substrate specificity, with PG serving as a substrate while phosphatidylethanolamine (PE), phosphatidylcholine (PC), and phosphatidylserine (PS) do not. Lastly, we show that this in vitro assay can be used to study the enzyme functions of other members of this protein family, such as the Listeria monocytogenes LTA synthase (LtaS_Lm) and LTA primase (LtaP_Lm) enzymes. This study is the first in vitro characterization of lipoteichoic acid synthase enzymes and an important first step towards the development of an assay to screen and identify enzyme-specific inhibitors for this new and important class of bacterial enzymes.     

Generation and Properties of a Streptococcus pneumoniae Mutant Which Does Not Require Choline or Analogs for Growth

A mutant (JY2190) of Streptococcus pneumoniae Rx1 which had acquired the ability to grow in the absence of choline and analogs was isolated. Lipoteichoic acid (LTA) and wall teichoic acid (TA) isolated from the mutant were free of phosphocholine and other phosphorylated amino alcohols. Both polymers showed an unaltered chain structure and, in the case of LTA, an unchanged glycolipid anchor. The cell wall composition was also not altered except that, due to the lack of phosphocholine, the phosphate content of cell walls was half that of the parent strain. Isolated cell walls of the mutant were resistant to hydrolysis by pneumococcal autolysin (N-acetylmuramyl-l-alanine amidase) but were cleaved by the muramidases CPL and cellosyl. The lack of active autolysin in the mutant cells became apparent by impaired cell separation at the end of cell division and by resistance against stationary-phase and penicillin-induced lysis. As a result of the absence of choline in the LTA, pneumococcal surface protein A (PspA) was no longer retained on the cytoplasmic membrane. During growth in the presence of choline, which was incorporated as phosphocholine into LTA and TA, the mutant cells separated normally, did not release PspA, and became penicillin sensitive. However, even under these conditions, they did not lyse in the stationary phase, and they showed poor reactivity with antibody to phosphocholine and an increased release of C-polysaccharide from the cell. In contrast to ethanolamine-grown parent cells (A. Tomasz, Proc. Natl. Acad. Sci. USA 59:86–93, 1968), the choline-free mutant cells retained the capability to undergo genetic transformation but, compared to Rx1, with lower frequency and at an earlier stage of growth. The properties of the mutant could be transferred to the parent strain by DNA of the mutant.Pneumococci differ from other gram-positive bacteria in that their lipoteichoic acid (LTA) and wall teichoic acid (TA) have the same chain structure which is, moreover, unusually complex (Fig. ​(Fig.1):1): glycerophosphate is replaced by ribitol phosphate (7), and between the ribitol phosphate residues a tetrasaccharide is intercalated (23). It contains d-glucose, 2-acetamido-4-amino-2,4,6-trideoxy-d-galactose (AATGal), and two N-acetyl-d-galactosaminyl residues, one or both of which carry a phosphocholine residue at O-6 (references 3 and 12 and this report). Open in a separate windowFIG. 1Pneumococcal TA and LTA. As shown, in strain R6 most of the repeats carry two phosphocholine residues each, at O-6 of the N-acetyl-d-galactosaminyl residues (3, 12). In strain Rx1 and Rx1/AL⁻, most repeats contain one phosphocholine residue (this report) attached to O-6 of the non-ribitol-linked galactosaminyl residue (14).Pneumococci are not able to synthesize the choline required for the synthesis of these substituents. Moreover, choline is an essential growth factor (2, 30) but can be substituted in this function by nutritional ethanolamine (EA) (38). Phosphoethanolamine is incorporated into LTA and TA in place of phosphocholine (14), but it cannot replace phosphocholine functionally. Phosphocholine-substituted LTA serves to anchor pneumococcal surface protein A (PspA) to the outer layer of the cytoplasmic membrane, with choline-mediated interaction between membrane-associated LTA and the C-terminal repeat region of PspA. In EA-grown bacteria, PspA is no longer retained and is released into the surrounding medium (45). Phosphocholine substituents also play an essential role for the activity of the major pneumococcal autolysin, an N-acetylmuramyl-l-alanine amidase (38). This protein possesses a choline-binding C-terminal domain that is essential for activity but, unlike PspA, is not essential for retention on the pneumococcal cell surface (16, 32). Binding of phosphocholine-substituted LTA to this domain results in potent inhibition of the amidase (21). The inhibitory property is dependent on the micellar structure of LTA (13) and lost by deacylation (5). Phosphocholine-substituted LTA may also participate in the transport of the amidase through the cytoplasmic membrane from the cytosol (5), the location of its synthesis (15). It additionally effects the conversion of the inactive E form of the enzyme into the active C form (5). This conversion is likewise effected by the choline residues of cell wall-linked TA (33, 39). Furthermore, binding of the amidase to the choline residues of TA is prerequisite for the hydrolysis of cell walls by the enzyme (18, 22). It should be noted that the amidase is not essential for growth. Though the enzyme is completely inactive in EA grown cells, the growth rate is not affected. However, cell separation is impaired, and there is a loss of stationary-phase and penicillin-induced cell lysis (38, 40), as well as a loss of genetic transformation (38). After insertional inactivation of the autolysin gene (lytA), the autolysin-deficient mutants (Lyt⁻) grew normally (31) and did not even show impeded cell separation (41).In this report, we describe a mutant which acquired the ability to grow in the absence of choline and analogs. Except for the observation that [³H]choline-substituted LTA is not a precursor of [³H]choline-substituted TA (6), nothing is known about the biosyntheses of pneumococcal LTA and TA and the stage of biosynthesis at which phosphocholine is incorporated. Since the absence of choline incorporation might affect the structure of LTA and TA as well as the composition of cell walls, we included relevant analyses in our study.(A preliminary report of this work was presented in an overview on pneumococcal LTA and TA at the International Meeting on the Molecular Biology of Streptococcus pneumoniae and Its Diseases, Oeiras, Portugal, September 24 to 29, 1996 [10].)     

Production of crystalline surface-active glycolipids by a strain of torulopsis apicola

The conditions for the production of extracellular glycolipid with Torulopsis apicola IMET 43747 have been investigated. Different culture conditions resulted in the production of either water-soluble or crude crystalline glycolipids. Growth was always accompanied by a strong decrease of the pH-value in the reaction medium. Cultivation at pH-value below 2 yielded the water-soluble product. The addition of either sodium citrate or sodium hydroxide to correct the pH-value to 3, resulted in the formation of large amounts of crystalline glycolipids. Depending on the kind of carbon source and its relative concentration, the product concentration was 5–90 g 1⁻¹ with maximal yields of 0.46 g g⁻¹ (product per substrate) after growth on a mixture of plant oils and glucose. The crude crystalline glycolipid mixture can be separated from the culture medium by filtration. It is composed of 80% of one major crystalline glycolipid and different minor compounds. Purification by liquid chromatography on silica gel yields the pure compound. This main product is a nonionic glycolipid with remarkable interfacial activities.     

A new model of pneumococcal lipoteichoic acid structure resolves biochemical, biosynthetic, and serologic inconsistencies of the current model

Lipoteichoic acid (LTA) is an essential bacterial membrane polysaccharide (cell wall component) that is attached to the membrane via a lipid anchor. According to the currently accepted structure of pneumococcal LTA, the polysaccharide is comprised of several repeating units, each of which starts with glucose and ends with ribitol, with the lipid anchor predicted to be Glc(beta1-->3)AATGal(beta1-->3)Glc(alpha1-->3)-acyl(2)Gro, where AATGal is 2-acetamido-4-amino-2,4,6-trideoxy-D-galactose. However, this lipid anchor has not been detected in pneumococcal membranes. Furthermore, the currently accepted structure does not explain the Forssman antigen properties of LTA and predicts a molecular weight for LTA that is larger than its actual observed molecular weight. To resolve these problems, we used mass spectrometry to analyze the structure of LTA isolated from several pneumococcal strains. Our study found that the R36A pneumococcal strain produces LTA that is more representative of pneumococci than that previously characterized from the R6 strain. Analysis of LTA fragments obtained after hydrofluoric acid and nitrous treatments showed that the fragments were consistent with an LTA nonreducing terminus consisting of GalNAc(alpha1-->3)GalNAc(beta1-->, which is the minimal structure for the Forssman antigen. Based on these data, we propose a revised model of LTA structure: its polysaccharide repeating unit begins with GalNAc and ends with AATGal, and its lipid anchor is Glc(alpha1-->3)-acyl(2)Gro, a common lipid anchor found in pneumococcal membranes. This new model accurately predicts the observed molecular weights. The revised model should facilitate investigation of the relationship between LTA's structure and its function.     

Biosynthesis of D-alanyl-lipoteichoic acid: role of diglyceride kinase in the synthesis of phosphatidylglycerol for chain elongation.

Lipophilic and hydrophilic D-alanyl-lipoteichoic acids are elongated in Lactobacillus casei by the transfer of sn-glycerol 1-phosphate units from phosphatidylglycerol to the poly(glycerophosphate) moiety of the polymer. These sn-glycerol 1-phosphate units are added to the end of the poly(glycerophosphate) which is distal to the glycolipid anchor; 1,2-diglyceride results from this addition. The presence of a diglyceride kinase was suggested by the ATP-dependent phosphorylation of 1,2-diglyceride to phosphatidic acid. Inorganic phosphate was used to initiate the synthesis of lipophilic lipoteichoic acid (LTA) and the elongation of both lipophilic and hydrophilic LTA. Three observations suggest that phosphate and other anions play a role in the in vitro synthesis of LTA and its precursors. First, the conversion of 1,2-diglyceride to phosphatidic acid by diglyceride kinase was stimulated. Second, the synthesis of phosphatidylglycerol was increased. Third, the elongation of lipophilic and hydrophilic LTA was enhanced. These observations indicated that one effect of phosphate might be to enhance the utilization of 1,2-diglyceride for the synthesis of phosphatidic acid. This phospholipid is a precursor of phosphatidylglycerol, the donor of sn-glycerol 1-phosphate for elongation of LTA.     

Isolation and characterization of a glycolipid from Dictyostelium discoideum

A glycolipid was isolated from a lipid extract of the cellular slime mold Dictyostelium discoideum and characterized. From the results of analyses by thin-layer chromatography and infrared spectrometry, it was identified as a steryl glycoside. The steryl glycoside was further analyzed by gas-liquid chromatography/mass spectrometry as a trimethylsilyl ether derivative, and its quantitative and qualitative changes during the development of D. discoideum were examined. Δ²²-Stigmastenyl-d-glucoside was the major constituent of the steryl glycoside and comprised more than 90% of the total steryl glycoside fraction in cells at all stages of development. The content of the steryl glycoside was higher in vegetative-stage cells, late aggregation-stage cells, and 1-day sorocarps than in cells of other stages. The glycolipid fraction was often contaminated by a lipid which was also isolated and identified as a ceramide containing 2-hydroxy fatty acids and 4D-hydroxysphinganine.