Expression cloning and characterization of the C28 acyltransferase of lipid A biosynthesis in Rhizobium leguminosarum

An unusual feature of lipid A from plant endosymbionts of the Rhizobiaceae family is the presence of a 27-hydroxyoctacosanoic acid (C28) moiety. An enzyme that incorporates this acyl chain is present in extracts of Rhizobium leguminosarum, Rhizobium etli, and Sinorhizobium meliloti but not Escherichia coli. The enzyme transfers 27-hydroxyoctacosanate from a specialized acyl carrier protein (AcpXL) to the precursor Kdo2 ((3-deoxy-d-manno-octulosonic acid)2)-lipid IV(A). We now report the identification of five hybrid cosmids that direct the overexpression of this activity by screening approximately 4000 lysates of individual colonies of an R. leguminosarum 3841 genomic DNA library in the host strain S. meliloti 1021. In these heterologous constructs, both the C28 acyltransferase and C28-AcpXL are overproduced. Sequencing of a 9-kb insert from cosmid pSSB-1, which is also present in the other cosmids, shows that acpXL and the lipid A acyltransferase gene (lpxXL) are close to each other but not contiguous. Nine other open reading frames around lpxXL were also sequenced. Four of them encode orthologues of fatty acid and/or polyketide biosynthetic enzymes. AcpXL purified from S. meliloti expressing pSSB-1 is fully acylated, mainly with 27-hydroxyoctacosanoate. Expression of lpxXL in E. coli behind a T7 promoter results in overproduction in vitro of the expected R. leguminosarum acyltransferase, which is C28-AcpXL-dependent and utilizes (3-deoxy-d-manno-octulosonic acid)2-lipid IV(A) as the acceptor. These findings confirm that lpxXL is the structural gene for the C28 acyltransferase. LpxXL is distantly related to the lauroyltransferase (LpxL) of E. coli lipid A biosynthesis, but highly significant LpxXL orthologues are present in Agrobacterium tumefaciens, Brucella melitensis, and all sequenced strains of Rhizobium, consistent with the occurrence of long secondary acyl chains in the lipid A molecules of these organisms.     

Endotoxin biosynthesis in Pseudomonas aeruginosa: enzymatic incorporation of laurate before 3-deoxy-D-manno-octulosonate.

Unlike Escherichia coli, living cells of Pseudomonas aeruginosa can complete the fatty acylation of lipid A when the biosynthesis of 3-deoxy-D-manno-octulosonate (Kdo) is inhibited (R. C. Goldman, C. C. Doran, S. K. Kadam, and J. O. Capobianco, J. Biol. Chem. 263:5217-5233, 1988). In this study, we demonstrate the presence of a novel enzyme in extracts of P. aeruginosa that can transfer lauroyl-acyl carrier protein (ACP) to a tetraacyl disaccharide-1,4'-bis-phosphate precursor of lipid A (termed lipid IVA) that accumulates in Kdo-deficient mutants of E. coli. Comparable E. coli extracts cannot transfer laurate from lauroyl-ACP to lipid IVA, only to (Kdo)2-lipid IVA (K. A. Brozek, and C. R. H. Raetz, J. Biol. Chem. 265:15410-15417, 1990). P. aeruginosa extracts do not utilize myristoyl- or R-3-hydroxymyristoyl-ACP instead of lauroyl-ACP to acylate lipid IVA. Laurate incorporation in P. aeruginosa extracts is dependent upon time, protein concentration, and the presence of Triton X-100 but is inhibited by lauroyl-coenzyme A. P. aeruginosa extracts transfer only one laurate to lipid IVA, whereas E. coli extracts can transfer two laurates to (Kdo)2-lipid IVA. These results demonstrate that incorporation of laurate into lipid A does not require prior attachment of Kdo in all gram-negative bacteria.     

Effect of cold shock on lipid A biosynthesis in Escherichia coli. Induction At 12 degrees C of an acyltransferase specific for palmitoleoyl-acyl carrier protein

Palmitoleate is not present in lipid A isolated from Escherichia coli grown at 30 degrees C or higher, but it comprises approximately 11% of the fatty acyl chains of lipid A in cells grown at 12 degrees C. The appearance of palmitoleate at 12 degrees C is accompanied by a decline in laurate from approximately 18% to approximately 5.5%. We now report that wild-type E. coli shifted from 30 degrees C to 12 degrees C acquire a novel palmitoleoyl-acyl carrier protein (ACP)-dependent acyltransferase that acts on the key lipid A precursor Kdo2-lipid IVA. The palmitoleoyl transferase is induced more than 30-fold upon cold shock, as judged by assaying extracts of cells shifted to 12 degrees C. The induced activity is maximal after 2 h of cold shock, and then gradually declines but does not disappear. Strains harboring an insertion mutation in the lpxL(htrB) gene, which encodes the enzyme that normally transfers laurate from lauroyl-ACP to Kdo2-lipid IVA (Clementz, T., Bednarski, J. J., and Raetz, C. R. H. (1996) J. Biol. Chem. 271, 12095-12102) are not defective in the cold-induced palmitoleoyl transferase. Recently, a gene displaying 54% identity and 73% similarity at the protein level to lpxL was found in the genome of E. coli. This lpxL homologue, designated lpxP, encodes the cold shock-induced palmitoleoyl transferase. Extracts of cells containing lpxP on the multicopy plasmid pSK57 exhibit a 10-fold increase in the specific activity of the cold-induced palmitoleoyl transferase compared with cells lacking the plasmid. The elevated specific activity of the palmitoleoyl transferase under conditions of cold shock is attributed to greatly increased levels of lpxP mRNA. The replacement of laurate with palmitoleate in lipid A may reflect the desirability of maintaining the optimal outer membrane fluidity at 12 degrees C.     

Secondary Acylation of Vibrio cholerae Lipopolysaccharide Requires Phosphorylation of Kdo

The lipopolysaccharide of Vibrio cholerae has been reported to contain a single 3-deoxy-d-manno-octulosonic acid (Kdo) residue that is phosphorylated. The phosphorylated Kdo sugar further links the hexa-acylated V. cholerae lipid A domain to the core oliogosaccharide and O-antigen. In this report, we confirm that V. cholerae possesses the enzymatic machinery to synthesize a phosphorylated Kdo residue. Further, we have determined that the presence of the phosphate group on the Kdo residue is necessary for secondary acylation in V. cholerae. The requirement for a secondary substituent on the Kdo residue (either an additional Kdo sugar or a phosphate group) was also found to be critical for secondary acylation catalyzed by LpxL proteins from Bordetella pertussis, Escherichia coli, and Haemophilus influenzae. Although three putative late acyltransferase orthologs have been identified in the V. cholerae genome (Vc0212, Vc0213, and Vc1577), only Vc0213 appears to be functional. Vc0213 functions as a myristoyl transferase acylating lipid A at the 2′-position of the glucosamine disaccharide. Generally acyl-ACPs serve as fatty acyl donors for the acyltransferases required for lipopolysaccharide biosynthesis; however, in vitro assays indicate that Vc0213 preferentially utilizes myristoyl-CoA as an acyl donor. This is the first report to biochemically characterize enzymes involved in the biosynthesis of the V. cholerae Kdo-lipid A domain.Lipopolysaccharide (LPS),² the major surface molecule in the outer membrane of Gram-negative bacteria, is composed of three domains: lipid A, core oligosaccharide, and O-antigen (1). The core oligosaccharide is further divided into two distinct regions: inner and outer core. The inner core consists of the Kdo sugars, which are responsible for linking the core region to the lipid A moiety of LPS. Lipid A is the hydrophobic anchor of LPS and is the only portion of LPS required for activating the host innate immune response by interacting with Toll-like receptor 4 and the accessory molecule, MD2.Kdo-lipid A biosynthesis is a well conserved and ordered process among Gram-negative bacteria; however, not all Gram-negative bacteria produce similar lipid A structures (2). In Escherichia coli, the biosynthesis of the Kdo-lipid A domain occurs via a nine-step process, resulting in the production of a hexa-acylated lipid A structure known as Kdo₂-lipid A. Kdo₂-lipid A has long been thought to be essential for the viability of E. coli; however, viable suppressor strains have been isolated that lack the Kdo sugar (3). The late steps of the biosynthetic pathway involve the addition of the Kdo sugars and the secondary or “late” acyl chains. The enzyme responsible for the addition of the Kdo sugars is the Kdo transferase (WaaA). In E. coli, this enzyme is bifunctional, transferring two Kdo sugars to the lipid A precursor, lipid IV_A (4); however, other Gram-negative bacteria have been shown to possess a monofunctional or trifunctional WaaA, as is the case in Haemophilus influenzae (5) or Chlamydia trachomatis (6), respectively.Previous reports have shown that in E. coli, the addition of the Kdo sugars is critical for the functionality of the secondary acyltransferases (LpxL, LpxM, and LpxP). The E. coli late acyltransferase LpxL catalyzes the transfer of laurate (C12:0) to the acyl chain linked at the 2′-position of Kdo₂-lipid IV_A (7). LpxM then catalyzes the addition of a myristate (C14:0) to the 3′-linked acyl chain of the penta-acylated lipid A precursor (8). When E. coli experience cold shock conditions (temperatures below 20 °C), the late acyltransferase LpxP transfers a palmitoleate (C16:1) to the 2′-position of Kdo₂-lipid IV_A, replacing the C12:0 acyl chain transferred by LpxL (9). Lipid A secondary acyltransferases have been shown to primarily utilize acyl-acyl carrier proteins (acyl-ACPs) as their acyl chain donor; however, a recent report by Six et al. (10) has shown that purified E. coli LpxL is capable of utilizing acyl-coenzyme A (acyl-CoA) as an alternative acyl donor at a lesser rate.The Gram-negative bacteria Vibrio cholerae is the causative agent of the severe diarrheal disease cholera. Cholera is transmitted via the fecal-oral route by ingestion of contaminated drinking water or food. The World Health Organization reported ∼130,000 cases of cholera in 2005 with the majority occurring in Africa. There are two serogroups of V. cholerae capable of epidemic and pandemic disease: O1 and O139 (11). Previous structural analyses have revealed that these serogroups possess very different lipid A structures. The V. cholerae O1 lipid A structure was reported as hexa-acylated, bearing secondary acyl chains at the 2- and 2′-positions of phosphorylated Kdo-lipid A (11–13); however, V. cholerae O139 was reported as having an octa-acylated lipid A (see Fig. 1) (11, 14).Open in a separate windowFIGURE 1.Comparison of E. coli K12 lipid A species to V. cholerae O1 and V. cholerae O139 lipid A species. The covalent modifications of lipid A are indicated with dashed bonds, and the lengths of the acyl chains are indicated below each structure. The lipid A of E. coli K12 is a hexa-acylated structure, bearing two secondary acyl chains at the 2′- and 3′-positions. The E. coli lipid A structure is glycosylated at the 6′-position with two Kdo moieties and is phosphorylated at the 1- and 4′-positions of the disaccharide backbone. Similar to E. coli, the lipid A species of V. cholerae serogroup O1 is hexa-acylated, but with a symmetrical acyl chain distribution. The proposed lipid A structure of V. cholerae O139 is the octa-acylated structure. Both V. cholerae serogroups O1 and O139 reported lipid A species have a single Kdo sugar that is phosphorylated (red) and a phosphoethanolamine (magenta) attached to the 1-phosphate.Our report focuses on V. cholerae O1 El Tor, which is the predominant disease-causing strain worldwide. Because little attention has been given to the Kdo-lipid A domain of V. cholerae, we investigated the assembly of the inner core structure of V. cholerae O1 LPS and the late acylation steps. This report demonstrates the importance of a secondary negative charge on the primary Kdo sugar of lipid A for late acyltransferase activity in V. cholerae and in other Gram-negative bacteria. Also, we have identified the putative V. cholerae late acyltransferase, Vc0213 as the LpxL homolog, transferring a myristate (C14:0) to the 2′-position of V. cholerae lipid A. These initial findings provide us with the groundwork needed to investigate the modifications of the V. cholerae Kdo-lipid A structure, which may serve as attractive vaccine targets in future research.     

A mannosyl transferase required for lipopolysaccharide inner core assembly in Rhizobium leguminosarum. Purification,substrate specificity,and expression in Salmonella waaC mutants

The lipopolysaccharide (LPS) core domain of Gram-negative bacteria plays an important role in outer membrane stability and host interactions. Little is known about the biochemical properties of the glycosyltransferases that assemble the LPS core. We now report the purification and characterization of the Rhizobium leguminosarum mannosyl transferase LpcC, which adds a mannose unit to the inner 3-deoxy-d-manno-octulosonic acid (Kdo) moiety of the LPS precursor, Kdo(2)-lipid IV(A). LpcC containing an N-terminal His(6) tag was assayed using GDP-mannose as the donor and Kdo(2)-[4'-(32)P]lipid IV(A) as the acceptor and was purified to near homogeneity. Sequencing of the N terminus confirmed that the purified enzyme is the lpcC gene product. Mild acid hydrolysis of the glycolipid generated in vitro by pure LpcC showed that the mannosylation occurs on the inner Kdo residue of Kdo(2)-[4'-(32)P]lipid IV(A). A lipid acceptor substrate containing two Kdo moieties is required by LpcC, since no activity is seen with lipid IV(A) or Kdo-lipid IV(A). The purified enzyme can use GDP-mannose or, to a lesser extent, ADP-mannose (both of which have the alpha-anomeric configuration) for the glycosylation of Kdo(2)-[4'-(32)P]lipid IV(A). Little or no activity is seen with ADP-glucose, UDP-glucose, UDP-GlcNAc, or UDP-galactose. A Salmonella typhimurium waaC mutant, which lacks the enzyme for incorporating the inner l-glycero-d-manno-heptose moiety of LPS, regains LPS with O-antigen when complemented with lpcC. An Escherichia coli heptose-less waaC-waaF deletion mutant expressing the R. leguminosarum lpcC gene likewise generates a hybrid LPS species consisting of Kdo(2)-lipid A plus a single mannose residue. Our results demonstrate that heterologous lpcC expression can be used to modify the structure of the Salmonella and E. coli LPS cores in living cells.     

A novel secondary acyl chain in the lipopolysaccharide of Bordetella pertussis required for efficient infection of human macrophages

Lipopolysaccharide is one of the major constituents of the Gram-negative bacterial outer membrane and is a potent stimulator of the host innate immune response. The biosynthesis of the lipid A moiety of lipopolysaccharide is a complex process in which multiple gene products are involved. Two late lipid A acyl transferases, LpxL and LpxM, were first identified in Escherichia coli and shown to be responsible for the addition of secondary acyl chains to the 2' and 3' positions of lipid A, respectively. Here, we describe the identification of two lpxL homologues in the genome of Bordetella pertussis. We show that one of them, LpxL2, is responsible for the addition of the secondary myristate group that is normally present at the 2' position of B. pertussis lipid A, whereas the other one, LpxL1, mediates the addition of a previously unrecognized secondary 2-hydroxy laurate at the 2 position. Increased expression of lpxL1 results in the appearance of a hexa-acylated lipopolysaccharide form with strongly increased endotoxic activity. In addition, we show that an lpxL1-deficient mutant of B. pertussis displays a defect in the infection of human macrophages.     

Biosynthesis of endotoxins. Purification and catalytic properties of 3-deoxy-D-manno-octulosonic acid transferase from Escherichia coli.

The enzyme 3-deoxy-D-manno-octulosonic acid (Kdo) transferase is encoded by the kdtA gene of Escherichia coli and plays a key role in lipopolysaccharide biosynthesis. It transfers Kdo from CMP-Kdo to lipid A or its tetraacyldisaccharide-1,4'-bisphosphate precursor, lipid IVA. Using a strain that overproduces the transferase approximately 500-fold, we have purified the enzyme to near homogeneity. The subunit molecular mass is approximately 43 kDa. Activity is stimulated by Triton X-100, is maximal at pH 7, but does not require Mg2+. The apparent Km values for lipid IVA and CMP-Kdo are 52 and 88 microM, respectively. Vmax is 15-18 mumol/min/mg when both substrates are added near saturation at pH 8. The purified enzyme transfers 2 Kdo residues to lipid A precursors or analogs bearing four to six fatty acyl chains and a 4'-monosphosphate moiety. Activity is inhibited by polymixin B and Re endotoxin. At low Kdo concentrations small amounts of the intermediate, (Kdo)1-IVA, accumulate. When this substance is isolated and incubated with purified enzyme in the presence of CMP-Kdo, it is converted to (Kdo)2-IVA. Formation of (Kdo)1-IVA is also observed when purified enzyme is incubated with (Kdo)2-IVA and 5 mM CMP, demonstrating that Kdo transfer is reversible. In summary, Kdo transferase consists of a single bifunctional polypeptide that incorporates the 2 innermost Kdo residues common to all lipopolysaccharide molecules in E. coli.     

An inner membrane dioxygenase that generates the 2-hydroxymyristate moiety of Salmonella lipid A

The lipid A residues of certain Gram-negative bacteria, including most strains of Salmonella and Pseudomonas, are esterified with one or two secondary S-2-hydroxyacyl chains. The S-2 hydroxylation process is O 2-dependent in vivo, but the relevant enzymatic pathways have not been fully characterized because in vitro assays have not been developed. We previously reported that expression of the Salmonella lpxO gene confers upon Escherichia coli K-12 the ability to synthesize 2-hydroxymyristate modified lipid A ( J. Biol. Chem. (2000) 275, 32940-32949). We now demonstrate that inactivation of lpxO, which encodes a putative Fe (2+)/O 2/alpha-ketoglutarate-dependent dioxygenase, abolishes S-2-hydroxymyristate formation in S. typhimurium. Membranes of E. coli strains expressing lpxO are able to hydroxylate Kdo 2-[4'- (32)P]-lipid A in vitro in the presence of Fe (2+), O 2, alpha-ketoglutarate, ascorbate, and Triton X-100. The Fe (2+) chelator 2,2'-bipyridyl inhibits the reaction. The product generated in vitro is a monohydroxylated Kdo 2-lipid A derivative. The [4'- (32)P]-lipid A released by mild acid hydrolysis from the in vitro product migrates with authentic S-2-hydroxlyated lipid A isolated from (32)P-labeled S. typhimurium cells. Electrospray ionization mass spectrometry and gas chromatography/mass spectrometry of the in vitro product are consistent with the 2-hydroxylation of the 3'-secondary myristoyl chain of Kdo 2-lipid A. LpxO contains two predicted trans-membrane helices (one at each end of the protein), and its active site likely faces the cytoplasm. LpxO is an unusual example of an integral membrane protein that is a member of the Fe (2+)/O 2/alpha-ketoglutarate-dependent dioxygenase family.     

A deacylase in Rhizobium leguminosarum membranes that cleaves the 3-O-linked beta-hydroxymyristoyl moiety of lipid A precursors

Lipid A from the nitrogen-fixing bacterium Rhizobium leguminosarum displays many structural differences compared with lipid A of Escherichia coli. R. leguminosarum lipid A lacks the usual 1- and 4'-phosphate groups but is derivatized with a galacturonic acid substituent at position 4'. R. leguminosarum lipid A often contains an aminogluconic acid moiety in place of the proximal glucosamine 1-phosphate unit. Striking differences also exist in the secondary acyl chains attached to E. coli versus R. leguminosarum lipid A, specifically the presence of 27-hydroxyoctacosanoate and the absence of laurate and myristate in R. leguminosarum. Recently, we have found that lipid A isolated by pH 4.5 hydrolysis of R. leguminosarum cells is more heterogeneous than previously reported (Que, N. L. S., Basu, S. S., White, K. A., and Raetz, C. R. H. (1998) FASEB J. 12, A1284 (abstr.)). Lipid A species lacking the 3-O-linked beta-hydroxymyristoyl residue on the proximal unit contribute to this heterogeneity. We now describe a membrane-bound deacylase from R. leguminosarum that removes a single ester-linked beta-hydroxymyristoyl moiety from some lipid A precursors, including lipid X, lipid IVA, and (3-deoxy-D-manno-octulosonic acid)2-lipid IVA. The enzyme does not cleave E. coli lipid A or lipid A precursors containing an acyloxyacyl moiety on the distal glucosamine unit. The enzyme is not present in extracts of E. coli or Rhizobium meliloti, but it is readily demonstrable in membranes of Pseudomonas aeruginosa, which also contains a significant proportion of 3-O-deacylated lipid A species. Optimal reaction rates are seen between pH 5.5 and 6.5. The enzyme requires a nonionic detergent and divalent metal ions for activity. It cleaves the monosaccharide lipid X at about 5% the rate of lipid IVA and (3-deoxy-D-manno-octulosonic acid)2-lipid IVA. 1H NMR spectroscopy of the deacylase reaction product, generated with lipid IVA as the substrate, confirms unequivocally that the enzyme cleaves only the ester-linked beta-hydroxymyristoyl residue at the 3-position of the glucosamine disaccharide.     

ATPase activity of the MsbA lipid flippase of Escherichia coli

Escherichia coli MsbA, the proposed inner membrane lipid flippase, is an essential ATP-binding cassette transporter protein with homology to mammalian multidrug resistance proteins. Depletion or loss of function of MsbA results in the accumulation of lipopolysaccharide and phospholipids in the inner membrane of E. coli. MsbA modified with an N-terminal hexahistidine tag was overexpressed, solubilized with a nonionic detergent, and purified by nickel affinity chromatography to approximately 95% purity. The ATPase activity of the purified protein was stimulated by phospholipids. When reconstituted into liposomes prepared from E. coli phospholipids, MsbA displayed an apparent K(m) of 878 microm and a V(max) of 37 nmol/min/mg for ATP hydrolysis in the presence of 10 mm Mg(2+). Preincubation of MsbA-containing liposomes with 3-deoxy-d-mannooctulosonic acid (Kdo)(2)-lipid A increased the ATPase activity 4-5-fold, with half-maximal stimulation seen at 21 microm Kdo(2)-lipid A. Addition of Kdo(2)-lipid A increased the V(max) to 154 nmol/min/mg and decreased the K(m) to 379 microm. Stimulation was only seen with hexaacylated lipid A species and not with precursors, such as diacylated lipid X or tetraacylated lipid IV(A). MsbA containing the A270T substitution, which renders cells temperature-sensitive for growth and lipid export, displayed ATPase activity similar to that of the wild type protein at 30 degrees C but was significantly reduced at 42 degrees C. These results provide the first in vitro evidence that MsbA is a lipid-activated ATPase and that hexaacylated lipid A is an especially potent activator.     

A novel 3-deoxy-D-manno-octulosonic acid (Kdo) hydrolase that removes the outer Kdo sugar of Helicobacter pylori lipopolysaccharide

The lipid A domain anchors lipopolysaccharide (LPS) to the outer membrane and is typically a disaccharide of glucosamine that is both acylated and phosphorylated. The core and O-antigen carbohydrate domains are linked to the lipid A moiety through the eight-carbon sugar 3-deoxy-D-manno-octulosonic acid known as Kdo. Helicobacter pylori LPS has been characterized as having a single Kdo residue attached to lipid A, predicting in vivo a monofunctional Kdo transferase (WaaA). However, using an in vitro assay system we demonstrate that H. pylori WaaA is a bifunctional enzyme transferring two Kdo sugars to the tetra-acylated lipid A precursor lipid IV(A). In the present work we report the discovery of a Kdo hydrolase in membranes of H. pylori capable of removing the outer Kdo sugar from Kdo2-lipid A. Enzymatic removal of the Kdo group was dependent upon prior removal of the 1-phosphate group from the lipid A domain, and mass spectrometric analysis of the reaction product confirmed the enzymatic removal of a single Kdo residue by the Kdo-trimming enzyme. This is the first characterization of a Kdo hydrolase involved in the modification of gram-negative bacterial LPS.     

The LpxL acyltransferase is required for normal growth and penta‐acylation of lipid A in Burkholderia cenocepacia

Lipid A anchors the lipopolysaccharide (LPS) to the outer membrane and is usually composed of a hexa‐acylated diglucosamine backbone. Burkholderia cenocepacia, an opportunistic pathogen, produces a mixture of tetra‐ and penta‐acylated lipid A. “Late” acyltransferases add secondary acyl chains to lipid A after the incorporation of four primary acyl chains to the diglucosamine backbone. Here, we report that B. cenocepacia has only one late acyltransferase, LpxL (BCAL0508), which adds a myristoyl chain to the 2′ position of lipid A resulting in penta‐acylated lipid A. We also identified PagL (BCAL0788), which acts as an outer membrane lipase by removing the primary β ‐hydroxymyristate (3‐OH‐C14:0) chain at the 3 position, leading to tetra‐acylated lipid A. Unlike PagL, LpxL depletion caused reduced cell growth and defects in cell morphology, both of which were suppressed by overexpressing the LPS flippase MsbA (BCAL2408), suggesting that lipid A molecules lacking the fifth acyl chain contributed by LpxL are not good substrates for the flippase. We also show that intracellular B. cenocepacia within macrophages produced more penta‐acylated lipid A, suggesting lipid A penta‐acylation in B. cenocepacia is required not only for bacterial growth and morphology but also for adaptation to intracellular lifestyle.     

Identification of a broad family of lipid A late acyltransferases with non‐canonical substrate specificity

Most Gram‐negative organisms produce lipopolysaccharide (LPS), a complex macromolecule anchored to the bacterial membrane by the lipid A moiety. Lipid A is synthesized via the Raetz pathway, a conserved nine‐step enzymatic process first characterized in Escherichia coli. The Epsilonproteobacterium Helicobacter pylori uses the Raetz pathway to synthesize lipid A; however, only eight of nine enzymes in the pathway have been identified in this organism. Here, we identify the missing acyltransferase, Jhp0255, which transfers a secondary acyl chain to the 3′‐linked primary acyl chain of lipid A, an activity similar to that of E. coli LpxM. This enzyme, reannotated as LpxJ due to limited sequence similarity with LpxM, catalyses addition of a C12:0 or C14:0 acyl chain to the 3′‐linked primary acyl chain of lipid A, complementing an E. coli LpxM mutant. Enzymatic assays demonstrate that LpxJ and homologues in Campylobacter jejuni and Wolinella succinogenes can act before the 2′ secondary acyltransferase, LpxL, as well as the 3‐deoxy‐d ‐manno‐octulosonic acid (Kdo) transferase, KdtA. Ultimately, LpxJ is one member of a large class of acyltransferases found in a diverse range of organisms that lack an E. coli LpxM homologue, suggesting that LpxJ participates in lipid A biosynthesis in place of an LpxM homologue.     

Deciphering the unusual acylation pattern of Helicobacter pylori lipid A

The synthesis of “typical” hexa-acylated lipid A occurs via a nine-step enzymatic pathway, which is generally well conserved throughout all gram-negative bacteria. One exception to the rule is Helicobacter pylori, which has only eight homologs to the nine lipid A biosynthetic enzymes. The discrepancy occurs toward the end of the pathway, with H. pylori containing only a single putative secondary acyltransferase encoded by jhp0265. In Escherichia coli K-12, two late acyltransferases, termed LpxL and LpxM, are required for the biosynthesis of hexa-acylated lipid A. Detailed biochemical and genetic analyses reveal that H. pylori Jhp0265 (the protein encoded by jhp0265) is in fact an LpxL homolog, capable of transferring a stearoyl group to the hydroxyl group of the 2′ linked fatty acyl chain of lipid A. Despite the lack of a homolog to LpxM in the H. pylori genome, the organism synthesizes a hexa-acylated lipid A species, suggesting that an equivalent enzyme exists. Using radiolabeled lipid A substrates and acyl-acyl carrier protein as the fatty acyl donor, we were able to confirm the presence of a second H. pylori late acyl transferase by biochemical assays. After synthesis of the hexa-acylated lipid A species, several modification enzymes then function to produce the major lipid A species of H. pylori that is tetra-acylated. Jhp0634 was identified as an outer membrane deacylase that removes the 3′-linked acyl chains of H. pylori lipid A. Together, this work elucidates the biochemical machinery required for the acylation and deacylation of the lipid A domain of H. pylori lipopolysaccharide.     

Mass spectrometry advances in lipidomica: collision-induced decomposition of Kdo2-lipid A

Mass spectrometry has made significant advances in the analysis of lipid substances, both simple and complex present in extracts of eukaryotic and prokaryotic cells. The development of the ionization techniques of electrospray ionization and matrix-assisted laser desorption ionization (MALDI) have both been applied to the analysis of lipids. The example of the types of structural information that can be obtained from MALDI-TOF tandem mass spectrometry is exemplified by the analysis of Kdo2-lipid A, a complex lipopolysaccharide known to activate toll-like 4 receptors on mammalian cells. Analysis of Kdo2-lipid A obtained from an Escherichia coli WBB06 was found to generate an abundant [M-H]- ion at m/z 2236.4 and a more abundant carbon-13 isotope at m/z 2237.4. Furthermore, collisional activation of the lipid A portion of the molecule at m/z 1796.3 resulted in a series of ions corresponding to the loss of all four fatty acyl groups as neutral carboxylic acids. An altogether different challenge of mass spectrometry applied to the area of lipid analysis is that of quantitative analysis. Two rather different requirements have emerged. One with high precision and accuracy for the measurement of relatively few lipid species that are produced at very low concentrations and typically interact with specific receptor proteins. A rather different challenge is that for the analysis of abundant lipid classes, which are composed of multiple molecular species that can approach several hundred under certain circumstances.     

Relaxed sugar donor selectivity of a Sinorhizobium meliloti ortholog of the Rhizobium leguminosarum mannosyl transferase LpcC. Role of the lipopolysaccharide core in symbiosis of Rhizobiaceae with plants

The lpcC gene of Rhizobium leguminosarum and the lpsB gene of Sinorhizobium meliloti encode protein orthologs that are 58% identical over their entire lengths of about 350 amino acid residues. LpcC and LpsB are required for symbiosis with pea and Medicago plants, respectively. S. meliloti lpsB complements a mutant of R. leguminosarum defective in lpcC, but the converse does not occur. LpcC encodes a highly selective mannosyl transferase that utilizes GDP-mannose to glycosylate the inner 3-deoxy-D-manno-octulosonic acid (Kdo) residue of the lipopolysaccharide precursor Kdo(2)-lipid IV(A). We now demonstrate that LpsB can also efficiently mannosylate the same acceptor substrate as does LpcC. Unexpectedly, however, the sugar nucleotide selectivity of LpsB is greatly relaxed compared with that of LpcC. Membranes of the wild-type S. meliloti strain 2011 catalyze the glycosylation of Kdo(2)-[4'-(32)P]lipid IV(A) at comparable rates using a diverse set of sugar nucleotides, including GDP-mannose, ADP-mannose, UDP-glucose, and ADP-glucose. This complex pattern of glycosylation is due entirely to LpsB, since membranes of the S. meliloti lpsB mutant 6963 do not glycosylate Kdo(2)-[4'-(32)P]lipid IV(A) in the presence of any of these sugar nucleotides. Expression of lpsB in E. coli using a T7lac promoter-driven construct results in the appearance of similar multiple glycosyl transferase activities seen in S. meliloti 2011 membranes. Constructs expressing lpcC display only mannosyl transferase activity. We conclude that LpsB, despite its high degree of similarity to LpcC, is a much more versatile glycosyltransferase, probably accounting for the inability of lpcC to complement S. meliloti lpsB mutants. Our findings have important implications for the regulation of core glycosylation in S. meliloti and other bacteria containing LpcC orthologs.     

Acyloxyacyl hydrolase, a leukocyte enzyme that deacylates bacterial lipopolysaccharides, has phospholipase, lysophospholipase, diacylglycerollipase, and acyltransferase activities in vitro.

Human acyloxyacyl hydrolase (AOAH) is a leukocyte enzyme that hydrolyzes acyloxyacyl bonds in the lipid A region of bacterial lipopolysaccharide (LPS), thereby detoxifying the LPS. We report here that the enzyme also acts in vitro on glycerophospholipids, lysophospholipids, and diacylglycerol. While AOAH preferentially removes palmitate or stearate from the sn-1 position of phospholipid and diacylglycerol substrates that have unsaturated acyl chains in the sn-2 position, it is able to cleave both palmitates from sn-1,2-dipalmitoylphosphatidylcholine and sn-1,2-dipalmitoylglycerol. This apparent preference for removing saturated (or shorter) acyl chains from glycerolipids is consistent with its ability to cleave laurate more rapidly than palmitoleate from lipopolysaccharide (Erwin, A. L., and Munford, R. S. (1990) J. Biol. Chem. 265, 16444-16449). AOAH also catalyzes acyl transfer from LPS and phosphatidylethanolamine to acceptor lipids; approximately equal amounts of laurate and myristate are transferred from LPS to monooleoylglyceryl ether, forming acyloleoylglyceryl ether. The demonstration that AOAH has phospholipase, lysophospholipase, diacylglycerol lipase, and acyltransferase activities in vitro suggests that the enzyme may have roles in addition to LPS deacylation (detoxification) in phagocytic cells.     

Detection of the abundance of diacylglycerol and triacylglycerol molecular species in cells using neutral loss mass spectrometry

Triacylglycerols (TAGs) are neutral lipids present in all mammalian cells as energy reserves, and diacylglycerols (DAGs) are present as intermediates in phospholipid biosynthesis and as signaling molecules. The molecular species of TAGs and DAGs present in mammalian cells are quite complex, and previous investigations revealed multiple isobaric species having molecular weights at virtually every even mass between 600 and 900 Da, making it difficult to assess changes of individual molecular species after cell activation. A method has been developed, using tandem MS and neutral loss scanning, to quantitatively analyze changes in those glyceryl ester molecular species containing identical fatty acyl groups. This was carried out by neutral loss scanning of 18 common fatty acyl groups where the neutral loss corresponded to the free carboxylic acid plus NH(3). Deuterium-labeled internal standards were used to normalize the signal for each nominal [M+NH(4)](+) ion undergoing this neutral loss reaction. This method was applied in studies of TAGs in RAW 264.7 cells treated with the toll-like receptor 4 ligand Kdo(2)-lipid A. A 50:1-TAG containing 18:1 was found to increase significantly over a 24-h time course after Kdo(2)-lipid A exposure, whereas an isobaric 50:1-TAG containing 16:1 did not change relative to controls.     

Biosynthesis of a structurally novel lipid A in Rhizobium leguminosarum: identification and characterization of six metabolic steps leading from UDP-GlcNAc to 3-deoxy-D-manno-2-octulosonic acid2-lipid IVA.

Lipopolysaccharides (LPSs) are prominent structural components of the outer membranes of gram-negative bacteria. In Rhizobium spp. LPS functions as a determinant of the nitrogen-fixing symbiosis with legumes. LPS is anchored to the outer surface of the outer membrane by the lipid A moiety, the principal lipid component of the outer bacterial surface. Several notable structural differences exist between the lipid A of Escherichia coli and that of Rhizobium leguminosarum, suggesting that diverse biosynthetic pathways may also exist. These differences include the lack of phosphate groups and the presence of a 4'-linked GalA residue in the latter. However, we now show that UDP-GlcNAc plays a key role in the biosynthesis of lipid A in R. leguminosarum, as it does in E. coli. 32P-labeled monosaccharide and disaccharide lipid A intermediates from E. coli were isolated and tested as substrates in cell extracts of R. leguminosarum biovars phaseoli and viciae. Six enzymes that catalyze the early steps of E. coli lipid A biosynthesis were also present in extracts of R. leguminosarum. Our results show that all the enzymes of the pathway leading to the formation of the intermediate 3-deoxy-D-manno-2-octulosonic acid (Kdo2)-lipid IVA are functional in both R. leguminosarum biovars. These enzymes include (i) UDP-GlcNAc 3-O-acyltransferase; (ii) UDP-3-O-(R-3-hydroxymyristoyl)-GlcNAc deacetylase; (iii) UDP-3-O-(R-3-hydroxymyristoyl)-GlcN N-acyltransferase; (iv) disaccharide synthase; (v) 4'-kinase; and (vi) Kdo transferase. Our data suggest that the early steps in lipid A biosynthesis are conserved and that the divergence leading to rhizobial lipid A may occur at a later stage in the pathway, presumably after the attachment of the Kdo residues.     

Deacylation of structurally diverse lipopolysaccharides by human acyloxyacyl hydrolase

Acyloxyacyl hydrolase, a leukocyte enzyme previously has been shown to catalyze the hydrolysis of secondary (acyloxyacyl-linked) fatty acyl chains from the nonreducing glucosamine of the lipid A region of rough Salmonella typhimurium lipopolysaccharide (LPS). We describe here the activity of this enzyme toward smooth S. typhimurium LPS and LPS from Escherichia coli, Pseudomonas aeruginosa, Haemophilus influenzae, Neisseria meningitidis, and Neisseria gonorrhoeae. Acyloxyacyl hydrolase released the secondary acyl chains from all of these lipopolysaccharides, regardless of the location of the acyloxyacyl linkage on the diglucosamine backbone or the structure of the acyl chains. The two acyloxyacyl linkages present in each LPS molecule apparently were hydrolyzed separately, so that free fatty acids released from the different sites accumulated at different rates. The purified enzyme also removed greater than 90% of the secondary acyl chains in each LPS, indicating that the enzyme acts not only on intact LPS but also on LPS molecules that have only one secondary acyl chain. The enzyme did not release the glucosamine-linked 3-hydroxyacyl chains. The specificity and versatility of the enzyme for cleaving acyloxyacyl linkages suggest that it may be a useful reagent for studying the structure and bioactivities of lipopolysaccharides with diverse carbohydrate and lipid A structures.