Suppression of monocyte oxidative response by phenolic glycolipid I of Mycobacterium leprae

Mycobacterium leprae synthesizes a unique phenolic glycolipid (PGL-I) in abundant quantities. We studied the effect of PGL-I on the generation of superoxide anion (O2-) by stimulated human monocytes. Peripheral blood monocytes pretreated with PGL-I released less O2- when stimulated with M. leprae than did control monocytes. Monocytes pretreated with dimycocerosyl phthiocerol, mycoside A of Mycobacterium kansasii, or mycoside B of Mycobacterium microti, on the other hand, released O2- in quantities comparable to control monocytes in response to M. leprae stimulation. Monocyte O2- release in response to other stimuli of the oxidative metabolic burst, such as PMA, zymosan, Mycobacterium bovis Bacille Calmette-Guérin, or M. kansasii, was unaffected by lipid pretreatment. These findings demonstrate that PGL-I has a direct effect on monocyte O2- generation in response to M. leprae and suggest that PGL-I is a modulator of phagocytic cell function.     

Chemical basis of rough and smooth variation in mycobacteria.

Rough and smooth colony variants of Mycobacterium kansasii were compared with respect to surface glycolipid composition. Thin-layer chromatography of the native glycolipid antigens, gas chromatography of the constituent sugars, and in situ probing with an appropriate monoclonal antibody by colony dot blot enzyme-linked immunosorbent assay and immunogold labeling demonstrated that all M. kansasii strains of smooth colony morphology contain on their surfaces the recently described trehalose-containing lipooligosaccharides, whereas all rough variants were devoid of such surface antigens. Yet all strains, rough and smooth, contained another glycolipid, the M. kansasii-specific phenolic glycolipid. Previous studies by others had shown that the rough forms of M. kansasii persist longer than smooth variants in experimentally infected mice. Therefore, this study may provide some insight into the question of the chemical basis of pathogenesis in certain mycobacteria.     

Structure of the major triglycosyl phenol-phthiocerol of Mycobacterium tuberculosis (strain Canetti)

Phenol-phthiocerol glycolipids have been found previously in Mycobacterium leprae, M. kansasii, M. bovis and M. marinum, but not in M. tuberculosis. A search for glycolipids in this latter species showed that the Canetti strains of M. tuberculosis synthesize a major triglycosyl phenol-phthiocerol, accompanied by minor amounts of other glycolipids with a similar aglycone moiety. The triglycoside moiety has the following structure: 2,3,4-tri-O-methyl L-fucopyranosyl(alpha 1----3)L-rhamnopyranosyl(alpha 1----3)2-O-methyl L-rhamnopyranosyl(alpha 1-. The aglycone moiety consists in phenol-phthiocerol (two homologs). Its two secondary alcohol functions are esterified by mycocerosic acids (homologs with 26-32 carbon atoms and with 2-4 methyl branches). The proposed structure differs on several points from the M. leprae glycolipids, but presents some analogy with the major glycolipid of M. kansasii. A minor monoglycosyl phenol-phthiocerol was also studied. Its overall structure is very similar to that of M. bovis, with 2-O-methyl rhamnose as sugar moiety.     

Characteristic new members of the phthiocerol and phenolphthiocerol families from Mycobacterium ulcerans

Diacyl phthiodiolone A and phenolphthiodiolone A lipids were isolated from two strains of Mycobacterium ulcerans. The diol units of the phthiodiolone A and phenolphthiodiolone A components were shown to have erythro stereochemistry by infrared spectroscopy and proton nuclear magnetic resonance of an acetal derivative. This stereochemistry is shared only by related diols from M. marinum, the diols from M. bovis, M. kansasii, M. leprae and M. tuberculosis having threo stereochemistry.     

A novel mannose containing phenolic glycolipid from Mycobacterium kansasii

Using high-performance liquid chromatography, a new kind of phenolic glycolipid quantitatively minor, called phenolic glycolipid-II, was isolated from a lipidic fraction of Mycobacterium kansasii. The structure was determined by fast atom bombardment-mass spectrometry and proton nuclear magnetic resonance spectroscopy, as: 2,4-di-O-Me-alpha-D-Manp(1----3) 4-O-Ac-2-O-Me-alpha-L-Fucp(1----3)2-O-Me- alpha-L-Rhap(1----3) 2,4-di-O-Me-alpha-L-Rhap 1----phenolphthiocerol dimycocerosate. Phenolic glycolipids I and II differ only by their distal monosaccharide hapten which is 2,6-dideoxy-4-O-Me-alpha-D-arabinohexopyranosyl and the 2,4-di-O-Me-alpha-D-mannopyranosyl, respectively. This sugar appears to be characteristic and apparently unique in the Mycobacterium genus. Moreover, phenolic glycolipids I and II constitute with the lipooligosaccharides two classes of antigens of M. kansasii.     

Exochelin-mediated iron acquisition by the leprosy bacillus, Mycobacterium leprae

Exochelins, water-soluble siderophores of mycobacteria, were isolated and partially purified from culture filtrates of iron-deficiently grown cultures of Mycobacterium neoaurum NCTC 10439 and an armadillo-derived Mycobacterium (ADM 8563). Two biologically active fractions mediating iron uptake were isolated from each bacterium which not only were able to transport iron into the producing organism but also into suspensions of Mycobacterium leprae isolated from armadillo liver. The rate of exochelin-mediated iron uptake into M. leprae was about 1.5% of the rate observed into the producing organisms. The process of iron uptake appears to be by facilitated diffusion as it was not inhibited by HgCl2, NaN3, KCN, dinitrophenol or carbonyl cyanide m-chlorophenylhydrazone. Since no uptake of iron occurred into iron-sufficient ADM cells, this may indicate that M. leprae, as recovered from an animal tissue, had been growing iron-deficiently in order for iron uptake to have been demonstrated in vitro.     

Structural elucidation of the major phenolic glycolipid from Mycobacterium kansasii. II. Presence of a novel dideoxyhexose

A novel O-methyl-2,6-dideoxyhexose was isolated from the major phenolic glycolipid (previously called mycoside A) of Mycobacterium kansasii. Its molecular weight (162) was determined by gas chromatography-mass spectrometry analysis (chemical ionization with ammonia as reactant gas) of its underivatized reducing form. The methoxyl group was located by electron impact-mass spectrometry of its alditol acetate. The configuration was established by 1H NMR of its peracetylated derivative. The structure 2,6-dideoxy-4-O-methyl-arabino-hexopyranose is proposed for this new sugar. Evidence is also presented that the phenolic glycolipid previously called mycoside A is an antigen of M. kansasii since it reacts with rabbit antisera raised against whole M. kansasii.     

Structural and immunological properties of the phenolic glycolipids from Mycobacterium gastri and Mycobacterium kansasii.

Mycobacterial species-specific antigens belong to the three following classes: phenolic glycolipids (Phe Gl), acyltrehalose-containing lipooligosaccharides and polar glycopeptidolipids. These antigens have been chemically defined and alkali-labile epitopes were found to characterize the lipooligosaccharide antigen type. In the present study the major Mycobacterium kansasii phenolic glycolipid epitope namely Phe Gl K-I was delineated as the distal monoacetylated disaccharidic residue: 2,6-dideoxy-4-O-methyl-alpha-D-arabino-hexopyranosyl-(1----3)-2-O-methyl -4-O- acetyl-alpha-L-fucopyranose. This acetoxy group is required for K-I epitope recognition demonstrating that alkali-labile epitopes also occur in the phenolic glycolipid antigen class. Using immunoelectron microscopy, the Phe Gl K-I epitope was localized around the electron-transparent layer on the M. kansasii cell-wall surface. Furthermore, two new phenolic glycolipids namely Phe Gl K-III and Phe Gl K-IV were discovered in minute amounts. They were purified and characterized by their retention time in direct-phase column HPLC. These molecules are also M. kansasii antigens, whose epitopes differ from that of Phe Gl K-I. The complete family of phenolic glycolipids Phe Gl K-I, K-II, K-III and K-IV was found in both rough and smooth variants of both M. kansasii and Mycobacterium gastri species.     

Carbohydrate epitope structural elucidation by 1H-NMR spectroscopy of a new Mycobacterium kansasii phenolic glycolipid antigen.

The complete primary structure of the carbohydrate moiety of a new phenolic glycolipid antigen namely PheGl K-IV from Mycobacterium kansasii was successfully established from only one- and two-dimensional 1H-NMR data. Among the scalar two-dimensional techniques, correlated spectroscopy with a 45 degree mixing pulse and phase-sensitive double-quantum-filtered correlated spectroscopy were selected, combined with two-dimensional dipolar techniques (nuclear Overhauser effect). These techniques using milligram of quantities native PheGl K-IV allowed the following monoacetylated tetrasaccharide to be proposed for its carbohydrate part: 4-O-Me-alpha-Manp-(1----3)-4-O-Ac-2-O-Me-alpha-Fucp-(1----3) -2-O-Me-alpha-Rhap- (1----3)-2,4-di-O-Me-alpha-Rhap. The PheGl K-IV shares, with the other phenolic glycolipids isolated from M. kansasii (K-I, K-II), a common core assigned to the lipid aglycone glycosylated by the monoacetylated trisaccharide part. It differs in the structure of the distal monosaccharide residue.     

DNA hybridization analysis of mycobacterial DNA using the 18-kDa protein gene of Mycobacterium leprae

Abstract DNA hybridization studies using a 611-base pair (bp) probe, encoding the entire 18-kDa protein of Mycobacterium leprae , demonstrated that M. simiae, M. intracellulare, M. kansasii, M. terrae , ADM-2, M. avium, M. scrofulaceum, M. gordonae and M. chelonei appear to posses DNA sequences homologous to the 18-kDa protein gene of M. leprae . RFLP analysis revealed that the restriction sites in the M. leprae 18-kDa gene were not conserved in the putative gene homologs of M. simiae and M. intracellulare . The restriction patterns observed with the 611-bp probe were useful in differentiating M. intracellulare, M. simiae , and M. leprae from each other, as well as in distinguishing strains of M. simiae serovar 1. Finally, the presence of homologous sequences in various mycobacteria did not affect the specificity of a previously described PCR test for detection of M. leprae , based on the M. leprae 18-kDa protein gene.     

A characteristic phenolic glycolipid antigen from Mycobacterium haemophilum

A characteristic phenolic glycolipid was detected, by thin layer chromatography, in non-polar lipid extracts of nine representative strains of Mycobacterium haemophilum . The lipid was a specific antigen that reacted strongly with serum raised against whole cells of M. haemophilum. Sera from six other mycobacterial strains were tested but only that from Mycobacterium kansasii give a weak reaction.     

Structure and antigenicity of the major specific glycolipid antigen of Mycobacterium leprae

Earlier we reported on the presence of a specific phenolic glycolipid (Phenolic Glycolipid-I) in Mycobacterium leprae, and in infected armadillo tissues (Hunter, S. W., and Brennan, P. J. (1981) J. Bacteriol. 147, 728-735). It had an inherent oligosaccharide, composed of 3-O-Me-rhamnose, 2,3-di-O-Me-rhamnose, and 3,6-di-O-Me-glucose, glycosidically linked to the phenol substituent. The structure of the oligosaccharide has now been determined, by partial acid hydrolysis, permethylation, 1H NMR, and 13C NMR as: 3,6-di-O-Me-Glcp(1 beta leads to 4)2,3-di-O-Me-Rhap(1 alpha leads to 2)3-O-Me-Rhap1 alpha leads to phenol (assuming that the glucose substituent is in the D-enantiomeric configuration, and the two methylated rhamnoses are L). Acid hydrolysis of deacylated Phenolic glycolipid-I yielded a phenolic phthiocerol "core," and mass spectrometry and proton NMR of the permethylated core suggested the following structure: (formula, see text) Combined gas-liquid chromatography-mass spectrometry showed three tetramethyl branched "mycocerosic" acids, C30, C32 and C34, with molecular weights (as methyl esters) of 466, 494, and 522, respectively. These are esterified to the hydroxyl functions of the branched glycolic chain. Evidence is also presented that the glycolipid is immunologically active, reacting with rabbit antisera to M. leprae and with sera from lepromatous leprosy patients.     

Active transport of ATP and presence of a vanadate-sensitive membrane-bound ATPase in Mycobacterium leprae.

It is not known how Mycobacterium leprae obtains energy for survival and growth in the host tissues; the organism does not grow in vitro. In the studies reported here, M. leprae incorporated labelled ATP, which was blocked by cyanide, unlabelled ATP or ADP, but not by adenosine or Pi. It seems that the organism takes up unhydrolysed ATP by an active transport process. The bacterium contained a membrane-bound, vanadate-sensitive E1 E2-ATPase (which creates a transmembrane potential driving transport of solutes into cells). The enzyme was not inhibited by N-ethylmaleimide, suggesting that it is not an F0F1-ATPase which catalyses ATP synthesis. Apparently, M. leprae derives energy-rich compounds from the host cell.     

The 16S rRNA nucleotide sequence of Mycobacterium leprae: phylogenetic position and development of DNA probes

The almost complete 16S rRNA sequence from Mycobacterium leprae was determined by direct sequencing of the chromosomal gene amplified by the polymerase chain reaction. The primary sequence revealed an insertion of 12 nucleotides at the 5' end of the 16S rRNA gene, which consists of an A-T stretch and appears to be unique for M. leprae. Within the mycobacteria M. leprae branches off with a group of slow-growing species comprising M. scrofulaceum, M. kansasii, M. szulgai, M. malmoense, M. intracellulare and M. avium. A systematic comparison of the nucleotide sequence resulted in the characterization of oligonucleotide probes which are highly specific for M. leprae. The probes hybridized exclusively to 16S rRNA nucleic acids from M. leprae, but not to nucleic acids from 20 cultivable fast- and slow-growing mycobacteria.     

Lipomannans,but not lipoarabinomannans,purified from Mycobacterium chelonae and Mycobacterium kansasii induce TNF-alpha and IL-8 secretion by a CD14-toll-like receptor 2-dependent mechanism

Lipoarabinomannans (LAMs) are glycolipids from the mycobacterial cell wall that exhibit various biological activities, including proinflammatory and anti-inflammatory responses. However, little is known about the properties of lipomannans (LMs), considered to be precursors of LAMs. In this study, we provide evidence that LMs purified from Mycobacterium chelonae and a clinical strain of Mycobacterium kansasii stimulated mRNA expression and secretion of TNF-alpha and IL-8 from human macrophage-like differentiated THP-1 cells. In contrast to LMs, LAMs were not able to induce a significant cytokine-inducing effect. The mechanism of activation by LMs was investigated using various Abs raised against surface receptors for multiple bacterial products. The presence of anti-CD14 or anti-Toll-like receptor 2 (TLR2) Abs profoundly affected production of TNF-alpha and IL-8, suggesting that both CD14 and TLR2 participate in the LM-mediated activation process. Furthermore, stimulation of cells was dependent on the presence of the LPS-binding protein, a plasma protein that transfers glycolipids to CD14. Chemical degradation of the arabinan domain of mannose-capped LAM from M. kansasii, which presented no cytokine-eliciting effect, restored the cytokine-inducing activity at a level similar to those of LMs. These results support the hypothesis that the presence of an arabinan in LAMs prevents the interaction of these glycolipids with TLR2/CD14 receptors. In addition, we found that phosphatidylinositol dimannosides isolated from M. kansasii did not induce cytokine secretion. This study suggests that LMs isolated from different mycobacterial species participate in the immunomodulation of the infected host and that the D-mannan core of this glycolipid is essential for this function.     

Mycobacterium kansasii in a rhesus monkey

The incidence of pulmonary disease caused by "atypical" mycobacteria has been increasing gradually in the human population since the 1950s. Mycobacterium kansasii and Mycobacterium intracellulare are the two organisms most responsible for this trend. A rhesus monkey was euthanatized and necropsied after reacting positive to mammalian Old Tuberculin on semi-annual testing. Histopathology demonstrated the presence of small numbers of acid fast organisms in pulmonary lesions. Further microbiological testing identified the causative organism as M. kansasii.     

ATP content of Mycobacterium tuberculosis grown in vivo and in vitro

In order to determine the reason for the slow growth of Mycobacterium leprae either in a host or in vitro, the growth characteristics of Mycobacterium tuberculosis were studied. The ATP content of in vitro-grown M. tuberculosis was about 520 pg/10(6) viable organisms. The ATP levels from in vivo-derived organisms obtained from liver and spleen of mice was about 130 pg (in cases of chronic infection) and about 270 pg (in cases of acute infection). When the in vivo-derived organisms were inoculated into culture medium, the growth rates for both types of organisms, acute as well as chronic infection, were the same and the maximum growth was reached during the fifth subculture. Although the maximum ATP content for both types of organism was the same, it was attained during the 4th subculture for organisms obtained during acute infection and during the 6th subculture for those obtained during chronic infection. The comparison between the ATP content of M. leprae and of M. tuberculosis indicates the reason for the slow growth of M. leprae.     

Subcellular localization of Mycobacterium leprae-specific phenolic glycolipid (PGL-I) antigen in human leprosy lesions and in M. leprae isolated from armadillo liver

Phenolic glycolipid (PGL-I), an antigen specific to Mycobacterium leprae, was localized subcellularly in M. leprae residing in human skin, in M. leprae isolated from armadillo liver ('isolated M. leprae') and outside M. leprae in human lepromatous skin. For a quantitative localization of PGL-I sites, specimens, including skin segments stored for 6 years in glutaraldehyde, were embedded in hydrophilic Lowicryl (K4M) resin for ultrathin sectioning. Ultracryosections and Araldite sections of comparable specimens were used for comparison of localization results. A monoclonal antibody (F 47-21-3) directed to antigenic oligosaccharide of PGL-I was employed as primary antibody in immunogold labelling of ultrathin sections. K4M-immunogold methods gave very satisfactory quantitative gold-labelling of PGL-I. The localization of PGL-I by this method partially corresponded with sites detectable in both ultracryosections and the qualititatively superior Araldite sections, but new sites were also localized. Cell walls in human M. leprae and in isolated M. leprae possessed many PGL-I sites, particularly in dividing organisms. PGL-I or its antigenic oligosaccharide was also found, to a lesser extent, in the bacterial cytoplasm. Capsules discernible around part of isolated M. leprae cells displayed heavy PGL-I labelling, sometimes clearly confined to a zone distant from the cell wall. Extrabacterial PGL-I in M. leprae-infected human skin was encountered (1) in phagolysosomes and cytoplasm proper of dermal macrophages containing M. leprae, and (2) intra- and extracellularly in epidermal areas where basal cells harboured M. leprae in untreated multibacillary patients.     

Interleukin-1 contributes to an effective clearance of Mycobacterium kansasii from the respiratory tract

Mycobacterium kansasii is an emerging pathogen that is able to induce pulmonary disease resembling tuberculosis. To determine the role of interleukin (IL-)1 in lung infection caused by this atypical mycobacterium, IL-1 receptor type 1 knockout (IL-1R(1) KO) and normal wild type mice were intranasally infected with M. kansasii. IL-1R(1) KO mice demonstrated a reduced antibacterial response in the lungs and an increased dissemination to the liver, which was accompanied by an enhanced pulmonary inflammatory response. These data identify IL-1 as an important component of the innate immune response to lung infection by M. kansasii.     

Detection of trehalose monomycolate in Mycobacterium leprae grown in armadillo tissues

Trehalose-6-monomycolate (TMM) was isolated from the lipids of armadillo-derived Mycobacterium leprae. Only meagre amounts of this glycolipid were recovered, but its structure was unequivocally established. Only alpha-mycolates were detected in the TMM by 252Cf plasma desorption mass spectrometry. Electron impact mass spectrometry showed the alpha branch to be principally C20. Trehalose dimycolate (cord factor) was not detectable. Since we have also found TMM in M. lepraemurium and in every Mycobacterium species so far examined, we suggest that this glycolipid is truly ubiquitous amongst mycobacteria.