Hemin-Dependent Modulation of the Lipid A Structure of Porphyromonas gingivalis Lipopolysaccharide
Porphyromonas gingivalis is a periopathogen strongly associated with the development of adult-type periodontitis. Both the virulence characteristics of periopathogens and host-related factors are believed to contribute to periodontitis. P. gingivalis lipopolysaccharide (LPS) displays a significant amount of lipid A structural heterogeneity, containing both penta-and tetra-acylated lipid A structures. However, little is known concerning how the lipid A structural content of P. gingivalis is regulated. Alterations in the lipid A content may facilitate the ability of P. gingivalis to modulate the innate host response to this bacterium. In this report, it is shown that the concentration of hemin in the growth medium significantly modulates the lipopolysaccharide lipid A structural content of P. gingivalis. Hemin is a key microenvironmental component of gingival cervicular fluid which is believed to vary depending upon the state of vascular ulceration. At low hemin concentrations, one major penta-acylated lipid A structure was found, whereas at high concentrations of hemin, multiple tetraand penta-acylated lipid A structures were observed. Hemin concentrations, not iron acquisition, were responsible for the alterations in the lipid A structural content. The modifications of the lipid A structural content were independent of the LPS extraction procedure and occurred in a variety of laboratory strains as well as a freshly obtained clinical isolate. The known hemin binding proteins Kgp and HmuR contributed to the lipid A modulation sensing mechanism. To the best of our knowledge, this is the first report that hemin, a clinically relevant microenvironmental component for P. gingivalis, can modulate the lipid A structure found in a bacterium. Since tetra-and penta-acylated P. gingivalis lipid A structures have opposing effects on Toll-like receptor 4 activation, the alteration of the lipid A structural content may have significant effects on the host response to this bacterium.Periodontitis is a chronic inflammatory disease of the tissue surrounding the tooth root surface. The disease is characterized by the loss of periodontal tissue and supporting alveolar bone. It is highly prevalent in the human population and is the major cause of tooth loss in the world (24). It is strongly associated with a subgingival microbial community (25) commonly referred to as periopathogenic dental plaque. Porphyromonas gingivalis, a gram-negative anaerobic bacterium, is a member of this community and displays a strong correlation with disease (25). Neither the contribution of periopathogenic plaque nor those of individual members of the periopathogenic community to the disease process are fully understood. However, it is suspected that both bacterial virulence factors, such as P. gingivalis protease secretion (17), and host factors contribute to the disease (18). The contribution of the host to the disease process is believed to result from an innate host response to periopathogenic bacteria that results in tissue damage and alveolar bone ...
Lipid A structural modifications can substantially impact the host's inflammatory response to bacterial LPS. Bacteroides fragilis, an opportunistic pathogen associated with life-threatening sepsis and intra-abdominal abscess formation, and Bacteroides thetaiotaomicron, a symbiont pivotal for proper host intestinal tissue development, both produce an immunostimulatory LPS comprised of penta-acylated lipid A. Under defined conditions, Porphyromonas gingivalis, an oral pathogen associated with periodontitis, also produces an LPS bearing a penta-acylated lipid A. However, this LPS preparation is 100-1000 times less potent than Bacteroides LPS in stimulating endothelial cells. We analyzed Bacteroides and P. gingivalis lipid A structures using MALDI-TOF MS and gas chromatography to determine the structural basis for this phenomenon. Even though both Bacteroides and P. gingivalis lipid A molecules are penta-acylated and mono-phosphorylated, subtle differences in mass and fatty acid content could account for the observed difference in LPS potency. This fatty acid heterogeneity is also responsible for the peak "clusters" observed in the mass spectra and obfuscates the correlation between LPS structure and immunostimulatory ability. Further, we show the difference in potency between Bacteroides and P. gingivalis LPS is TLR4-dependent. Altogether, the data suggest subtle changes in lipid A structure may profoundly impact the host's innate immune response.
SummaryLipopolysaccharides containing underacylated lipid A structures exhibit reduced abilities to activate the human (h) Toll-like receptor 4 (TLR4) signalling pathway and function as potent antagonists against lipopolysaccharides bearing canonical lipid A structures. Expression of underacylated lipopolysaccharides has emerged as a novel mechanism utilized by microbial pathogens to modulate host innate immune responses. Notably, antagonistic lipopolysaccharides are prime therapeutic candidates for combating Gram negative bacterial sepsis. Penta-acylated msbB and tetra-acylated Porphyromonas gingivalis lipopolysaccharides functionally antagonize hexa-acylated Escherichia coli lipopolysaccharide-dependent activation of hTLR4 through the coreceptor, hMD-2. Here, the molecular mechanism by which these antagonistic lipopolysaccharides act at hMD-2 is examined. We present evidence that both msbB and P. gingivalis lipopolysaccharides are capable of direct binding to hMD-2. These antagonistic lipopolysaccharides can utilize at least two distinct mechanisms to block E. coli lipopolysaccharide-dependent activation of hTLR4. The main mechanism consists of direct competition between the antagonistic lipopolysaccharides and E. coli lipopolysaccharide for the same binding site on hMD-2, while the secondary mechanism involves the ability of antagonistic lipopolysaccharide-hMD-2 complexes to inhibit E. coli lipopolysaccharide-hMD-2 complexes function at hTLR4. It is also shown that both hTLR4 and hMD-2 contribute to the species-specific recognition of msbB and P. gingivalis lipopolysaccharides as antagonists at the hTLR4 complex.
Acyl Chain Specificity of the Acyltransferases LpxA and LpxD and Substrate Availability Contribute to Lipid A Fatty Acid Heterogeneity in Porphyromonas gingivalis
Porphyromonas gingivalis lipid A is heterogeneous with regard to the number, type, and placement of fatty acids. Analysis of lipid A by matrix-assisted laser desorption ionization-time of flight mass spectrometry reveals clusters of peaks differing by 14 mass units indicative of an altered distribution of the fatty acids generating different lipid A structures. To examine whether the transfer of hydroxy fatty acids with different chain lengths could account for the clustering of lipid A structures, P. gingivalis lpxA (lpxA Pg ) and lpxD Pg were cloned and expressed in Escherichia coli strains in which the homologous gene was mutated. Lipid A from strains expressing either of the P. gingivalis transferases was found to contain 16-carbon hydroxy fatty acids in addition to the normal E. coli 14-carbon hydroxy fatty acids, demonstrating that these acyltransferases display a relaxed acyl chain length specificity. Both LpxA and LpxD, from either E. coli or P. gingivalis, were also able to incorporate odd-chain fatty acids into lipid A when grown in the presence of 1% propionic acid. This indicates that E. coli lipid A acyltransferases do not have an absolute specificity for 14-carbon hydroxy fatty acids but can transfer fatty acids differing by one carbon unit if the fatty acid substrates are available. We conclude that the relaxed specificity of the P. gingivalis lipid A acyltransferases and the substrate availability account for the lipid A structural clusters that differ by 14 mass units observed in P. gingivalis lipopolysaccharide preparations.Porphyromonas gingivalis is a gram-negative, asaccharolytic, anaerobic bacterium that is strongly associated with adult periodontitis (12,18,27). Its virulence factors include proteases (19,34,46), fimbria (2, 22, 54), hemagglutinins (17,23,35), and lipopolysaccharide (LPS) (3, 11, 13). LPS is a major component of the outer membrane of gram-negative bacteria. LPS contributes to the integrity of the bacterial cell envelope and is a strong modulator of the host innate immune system (3,5,9,10,13,14,16). Both positive and negative modulations of the host response by LPS are believed to play a role in the development of various infectious conditions (13,15,21,24,28,32,33,44,50). Most of this activity is known to be contained in the lipid portion of the LPS molecule known as lipid A (41, 51). Escherichia coli lipid A structure consists of a glucosamine disaccharide phosphorylated at the 1 and 4Ј positions and is substituted with four -hydroxy-myristates in amide linkage (2 and 2Ј positions) and in ester linkage (3 and 3Ј positions). The structure also contains a laurate in the secondary ester linkage on the 2Ј -hydroxy-myristate and a myristate in the secondary linkage on the 3Ј -hydroxy-myristate to generate the hexa-acyl lipid A canonical structure (51).P. gingivalis LPS is significantly different from E. coli in that it consists of a heterogeneous mixture of lipid A structures that differ in the type and number of fatty acids and the number of phosphate groups (1,26,40). Com...
The anti‐endotoxic effects of the KSL‐W decapeptide on Escherichia coli O55:B5 and various oral lipopolysaccharides
These results demonstrate that for the concentrations tested, the KSL-W decapeptide was nontoxic to mammalian cells and could bind to and block the host recognition and response towards enteric, as well as oral, lipopolysaccharide samples.
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