Structural reorganization of the antigen-binding groove of human CD1b for presentation of mycobacterial sulfoglycolipids.

The mechanisms permitting nonpolymorphic CD1 molecules to present lipid antigens that differ considerably in polar head and aliphatic tails remain elusive. It is also unclear why hydrophobic motifs in the aliphatic tails of some antigens, which presumably embed inside CD1 pockets, contribute to determinants for T-cell recognition. The 1.9-Å crystal structure of an active complex of CD1b and a mycobacterial diacylsulfoglycolipid presented here provides some clues. Upon antigen binding, endogenous spacers of CD1b, which consist of a mixture of diradylglycerols, moved considerably within the lipid-binding groove. Spacer displacement was accompanied by F' pocket closure and an extensive rearrangement of residues exposed to T-cell receptors. Such structural reorganization resulted in reduction of the A' pocket capacity and led to incomplete embedding of the methyl-ramified portion of the phthioceranoyl chain of the antigen, explaining why such hydrophobic motifs are critical for T-cell receptor recognition. Mutagenesis experiments supported the functional importance of the observed structural alterations for T-cell stimulation. Overall, our data delineate a complex molecular mechanism combining spacer repositioning and ligand-induced conformational changes that, together with pocket intricacy, endows CD1b with the required molecular plasticity to present a broad range of structurally diverse antigens.

Fatty acyl structures of mycobacterium tuberculosis sulfoglycolipid govern T cell response.

CD1b-restricted T lymphocytes recognize a large diversity of mycobacterial lipids, which differ in their hydrophilic heads and the structure of their acyl appendages. Both moieties participate in the antigenicity of lipid Ags, but the structural constraints governing binding to CD1b and generation of antigenic CD1b:lipid Ag complexes are still poorly understood. Here, we investigated the structural requirements conferring antigenicity to Mycobacterium tuberculosis sulfoglycolipid Ags using a combination of CD1b:lipid binding and T cell activation assays with both living dendritic cells and plate-bound recombinant soluble CD1b. Comparison of the antigenicity of a panel of synthetic analogs, sharing the same trehalose-sulfate polar head, but differing in the structure of their acyl tails, shows that the number of C-methyl substituents on the fatty acid, the configuration of the chiral centers, and the respective localization of the two different acyl chains on the sugar moiety govern TCR recognition and T lymphocyte activation. These studies have major implications for the design of sulfoglycolipid analogs with potential use as tuberculosis subunit vaccines.

Comparative investigation of the pathogenicity of three Mycobacterium tuberculosis mutants defective in the synthesis of p-hydroxybenzoic acid derivatives.

p-Hydroxybenzoic acid derivatives (p-HBADs) are glycoconjugates secreted by all Mycobacterium tuberculosis isolates whose contribution to pathogenicity remains to be determined. The pathogenicity of three transposon mutants of M. tuberculosis deficient in the biosynthesis of some or all forms of p-HBADs was studied. Whilst the mutants grew similarly to the wild-type strain in macrophages and C57BL/6 mice, two of the mutants induced a more severe and diffuse inflammation in the lungs. The lack of production of some or all forms of p-HBADs in these two mutants also correlated with an increased secretion of the pro-inflammatory cytokines tumour-necrosis factor alpha, interleukin 6 and interleukin 12 in vivo. We propose that the loss of production of p-HBADs by tubercle bacilli results in their diminished ability to suppress the pro-inflammatory response to infection and that this ultimately provokes extensive pulmonary lesions in the C57BL/6 model of tuberculosis infection.

Analysis of aminofluorescein-fatty acid derivatives by capillary electrophoresis with laser-induced fluorescence detection at the attomole level: application to mycobacterial fatty acids.

A method based on capillary electrophoresis coupled to laser-induced fluorescence detection was developed for the characterization of fatty acids including palmitic, stearic, oleic and tuberculostearic acids. The fatty acids were tagged by 4-aminofluorescein (AF) via a carboxylic acid-amine condensation promoted by N'-(3-dimethylaminopropyl)-N-ethylcarbodiimide (EDC) in non-aqueous solution. Using the optimized derivatization conditions, the fluorophore labeling of the fatty acids was achieved at the nanomolar level. The separation of palmitic, stearic, oleic and tuberculostearic-AF derivatives was achieved in less than 10 min, using 25 mM sodium borate buffer containing 30% of acetonitrile as running electrolyte. The concentration detection limit was found to be 5 nM while the minimum mass limit detection is around 30 attomol. This method was successfully applied to identification of mycobacteria via the characterization of tuberculostearic acid and found to be suitable for the detection of a minimum of 10(6) mycobacteria.

Structural analysis of mycobacterial lipoglycans.

Mycobacterium tuberculosis, the causative agent of tuberculosis, is one of the most effective human pathogens. The mycobacterial cell envelope contains lipoglycans, and of particular interest is lipoarabinomannan (LAM), one of the most potent mycobacterial immunomodulatory molecules. The importance of lipoarabinomannan (LAM) in the immunopathogenesis of tuberculosis has incited structural studies on this molecule to (1) establish a precise structural model of the molecule and (2) decipher the structure/function relationships. In recent years, we have focused on the two domains essential for LAM biologic activities: the mannosyl-phosphatidyl-myo-inositol anchor and the caps. We review here the recent procedures developed for the structural analysis of these domains.

Characterization of a truncated lipoarabinomannan from the Actinomycete Turicella otitidis.

Lipoarabinomannan (LAM) lipoglycans have been characterized from a range of mycolic acid-containing actinomycetes and from the amycolate actinomycete Amycolatopsis sulphurea. To further understand the structural diversity of this family, we have characterized the lipoglycan of the otic commensal Turicella otitidis. T. otitidis LAM (TotLAM) has been determined to consist of a mannosyl phosphatidylinositol anchor unit carrying an (alpha 1-->6)-linked mannan core and substituted with terminal-arabinosyl branches. Thus, TotLAM has a novel truncated LAM structure. Using the human monocytic THP-1 cell line, it was found that TotLAM exhibited only minimal ability to induce tumor necrosis factor alpha. These findings contribute further to our understanding of actinomycete LAM diversity and allow further speculation as to the correlation between LAM structure and the immunomodulatory activities of these lipoglycans.

Probing the orientation of reconstituted maltoporin channels at the single-protein level.

Recently we have shown that maltoporin channels reconstituted into black lipid membranes have pronounced asymmetric properties in both ion conduction and sugar binding. This asymmetry revealed also that maltoporin insertion is directional. However, the orientation in the lipid bilayer remained an open question. To elucidate the orientation, we performed point mutations at each side of the channel and analyzed the ion current fluctuation caused by an asymmetric maltohexaose addition. In a second series we used a chemically modified maltohexaose sugar molecule with inhibited entry possibility from the periplasmic side. In contrast to the natural outer cell wall of bacteria, we found that the maltoporin inserts in artificial lipid bilayer in such a way that the long extracellular loops are exposed to the same side of the membrane than protein addition. Based on this orientation, the directional properties of sugar binding were correlated to physiological conditions. We found that nature has optimized maltoporin channels by lowering the activation barriers at each extremity of the pore to trap sugar molecules from the external medium and eject them most efficiently to the periplasmic side.

Capillary electrophoresis analysis of glucooligosaccharide regioisomers.

Complex gluco-oligosaccharide mixtures of two regioisomer series were successfully separated by CE. The gluco-oligosaccharide series were synthesized, employing a dextransucrase from Leuconostoc mesenteroides NRRL B-512F, by successive glucopyranosyl transfers from sucrose to the acceptor glucose or maltose. The glucosyl transfer to both acceptors, occurring through the formation of alpha1-->6 linkages, differed for the two series only in the glucosidic bond to the reducing end namely alpha1-->6 or alpha1-->4 bond for glucose or maltose acceptor, respectively. Thus, the combination of the two series results in mixed pairs of gluco-oligosaccharide regioisomers with different degrees of polymerization (DP). These regioisomer series were first derivatized by reductive amination with 9-aminopyrene-1,4,6-trisulfonate (APTS). Under acidic conditions using triethyl ammonium acetate as electrolyte, the APTS-gluco-oligosaccharides of each series were separated enabling unambiguous size determination by coupling CE to electrospray-mass spectrometry. However, neither these acidic conditions nor alkaline buffer systems could be adapted for the separation of the gluco-oligosaccharide regioisomers arising from the two combined series. By contrast, increased resolution was observed in an alkaline borate buffer, using differential complexation of the regioisomers with the borate anions. Such conditions were also successfully applied to the separation of glucodisaccharide regioisomers composed of alpha1-->2, alpha1-->3, alpha1-->4, and alpha1-->6 linkages commonly synthesized by glucansucrase enzymes.

Tsukamurella paurometabola lipoglycan, a new lipoarabinomannan variant with pro-inflammatory activity.

The genus Tsukamurella is a member of the phylogenetic group nocardioform actinomycetes and is closely related to the genus Mycobacterium. The mycobacterial cell envelope contains lipoglycans, and of particular interest is lipoarabinomannan, one of the most potent mycobacterial immunomodulatory molecules. We have investigated the presence of lipoglycans in Tsukamurella paurometabola and report here the isolation and structural characterization of a new lipoarabinomannan variant, designated TpaLAM. Matrix-assisted laser desorption ionization-mass spectrometric analysis revealed that TpaLAM had an average molecular mass of 12.5 kDa and consequently was slightly smaller than Mycobacterium tuberculosis lipoarabinomannan. Using a range of chemical degradations, NMR experiments, capillary electrophoresis, and mass spectrometry analyses, TpaLAM revealed an original carbohydrate structure. Indeed, TpaLAM contained a mannosylphosphatidyl-myo-inositol (MPI) anchor glycosylated by a linear (alpha1-->6)-Manp mannan domain, which is further substituted by an (alpha1-->5)-Araf chain. Half of the Araf units are further substituted at the O-2 position by a Manp-(alpha1-->2)-Manp-(alpha1--> dimannoside motif. Altogether, TpaLAM appears to be the most elaborated non-mycobacterial LAM molecule identified to date. TpaLAM was found to induce the pro-inflammatory cytokine tumor necrosis factor (TNF)-alpha when tested with either human or murine monocyte/macrophage cell lines. This induction was completely abrogated in the presence of an anti-toll-like receptor-2 (TLR-2) antibody, suggesting that TLR-2 participates in the mediation of TNF-alpha production in response to TpaLAM. Moreover, we established that the lipomannan core of TpaLAM is the primary moiety responsible for the observed TNF-alpha-inducing activity. This conclusively demonstrates that a linear (alpha1-->6)-Manp chain, linked to the MPI anchor, is sufficient in providing pro-inflammatory activity.

A novel lipoarabinomannan from the equine pathogen Rhodococcus equi. Structure and effect on macrophage cytokine production.

Rhodococcus equi is a major cause of foal morbidity and mortality. We have investigated the presence of lipoglycan in this organism as closely related bacteria, notably Mycobacterium tuberculosis, produce lipoarabinomannans (LAM) that may play multiple roles as virulence determinants. The lipoglycan was structurally characterized by gas chromatography-mass spectrometry following permethylation, capillary electrophoresis after chemical degradation, and (1)H and (31)P and two-dimensional heteronuclear nuclear magnetic resonance studies. Key structural features of the lipoglycan are a linear alpha-1,6-mannan with side chains containing one 2-linked alpha-d-Manp residue. This polysaccharidic backbone is linked to a phosphatidylinositol mannosyl anchor. In contrast to mycobacterial LAM, there are no extensive arabinan domains but single terminal alpha-d-Araf residue capping the 2-linked alpha-d-Manp. The lipoglycan binds concanavalin A and mannose-binding protein consistent with the presence of t-alpha-d-Manp residues. We studied the ability of the lipoglycans to induce cytokines from equine macrophages, in comparison to whole cells of R. equi. These data revealed patterns of cytokine mRNA induction that suggest that the lipoglycan is involved in much of the early macrophage cytokine response to R. equi infection. These studies identify a novel LAM variant that may contribute to the pathogenesis of disease caused by R. equi.