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.     

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.     

Glycolipids of recent clinical isolates of Mycobacterium tuberculosis: chemical characterization and immunoreactivity

Five distinct glycolipids were readily detected in isolates of Mycobacterium tuberculosis. Spectroscopic methods and chemical degradation techniques allowed the structural identification of four of these glycolipids. The specific phenolic glycolipid antigen previously characterized from the Canetti strain was found in all the strains examined, with identical structural features (triglycosyl phenol phthiocerol dimycocerosate). The other three glycolipids identified were acylated trehaloses: penta-acyl trehalose (containing phthienoyl substituents), tetra-acyl trehalose 2'-sulphate (with C40-C50 hydroxyphthioceranoyl substituents) and diacyl trehalose 2'-sulphate (with C16 and C18 substituents). The two latter glycolipids as well as the phenolic glycolipid immunoreacted with whole-cell antiserum, indicating their surface location. The occurrence of these glycolipid antigens in recent clinical isolates suggests their possible utilization in the serodiagnosis of tuberculosis and the rapid identification of M. tuberculosis with specific antisera.     

Pyruvate oxidase is a determinant of Avery's rough morphology

In pioneering studies, Avery et al. identified DNA as the hereditary material (A. T. Avery, C. M. MacLeod, and M. McCarty, J. Exp. Med. 79:137-158, 1944). They demonstrated, by means of variation in colony morphology, that this substance could transform their rough type 2 Streptococcus pneumoniae strain R36A into a smooth type 3 strain. It has become accepted as fact, from modern textbook accounts of these experiments, that smooth pneumococci make capsule, while rough strains do not. We found that rough-to-smooth morphology conversion did not occur in rough strains R36A and R6 when the ability to synthesize native type 2 capsule was restored. The continued rough morphology of these encapsulated strains was attributed to a second, since-forgotten, morphology-affecting mutation that was sustained by R36A during strain development. We used a new genome-PCR-based approach to identify spxB, the gene encoding pyruvate oxidase, as the mutated locus in R36A and R6 that, with unencapsulation, gives rise to rough colony morphology, as we know it. The variant spxB allele of R36A and R6 is associated with increased cellular pyruvate oxidase activity relative to the ancestral strain D39. Increased pyruvate oxidase activity alters colony shape by mediating cell death. R36A requires a wild-type spxB allele for the expression of smooth type 2 morphology but not for the expression of smooth type 3 morphology, the phenotype monitored by Avery et al. Thus, the mutated spxB allele did not impact their use of smooth morphology to identify the transforming principle.     

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.     

Role of the pks15/1 gene in the biosynthesis of phenolglycolipids in the Mycobacterium tuberculosis complex. Evidence that all strains synthesize glycosylated p-hydroxybenzoic methyl esters and that strains devoid of phenolglycolipids harbor a frameshift mutation in the pks15/1 gene

Diesters of phthiocerol and phenolphthiocerol are important virulence factors of Mycobacterium tuberculosis and Mycobacterium leprae, the two main mycobacterial pathogens in humans. They are both long-chain beta-diols, and their biosynthetic pathway is beginning to be elucidated. Although the two classes of molecules share a common lipid core, phthiocerol diesters have been found in all the strains of the M. tuberculosis complex examined although phenolphthiocerol diesters are produced by only a few groups of strains. To address the question of the origin of this diversity 8 reference strains and 10 clinical isolates of M. tuberculosis were analyzed. We report the presence of glycosylated p-hydroxybenzoic acid methyl esters, structurally related to the type-specific phenolphthiocerol glycolipids, in the culture media of all reference strains of M. tuberculosis, suggesting that the strains devoid of phenolphthiocerol derivatives are unable to elongate the putative p-hydroxybenzoic acid precursor. We also show that all the strains of M. tuberculosis examined and deficient in the production of phenolphthiocerol derivatives are natural mutants with a frameshift mutation in pks15/1 whereas a single open reading frame for pks15/1 is found in Mycobacterium bovis BCG, M. leprae, and strains of M. tuberculosis that produce phenolphthiocerol derivatives. Complementation of the H37Rv strain of M. tuberculosis, which is devoid of phenolphthiocerol derivatives, with the fused pks15/1 gene from M. bovis BCG restored phenolphthiocerol glycolipids production. Conversely, disruption of the pks15/1 gene in M. bovis BCG led to the abolition of the synthesis of type-specific phenolphthiocerol glycolipid. These data indicate that Pks15/1 is involved in the elongation of p-hydroxybenzoic acid to give p-hydroxyphenylalkanoates, which in turn are converted, presumably by the PpsA-E synthase, to phenolphthiocerol derivatives.     

Mycolipenates and mycolipanolates of trehalose from mycobacterium tuberculosis

Analysis of the lipids of Mycobacterium tuberculosis, by thin-layer chromatography, revealed the presence of two families of novel glycolipids each having two closely-related members but differing widely in polarity. The least and most polar families of lipids were characterized from M. tuberculosis strains C and H37Rv, respectively; all were based on trehalose, the least polar pair of glycolipids having more long-chain substituents than the more polar pair. The acyl substituents of the least polar of the four glycolipids were mainly straight-chain C16 and C18 acids and 2,4,6-trimethyltetracos-2-enoic (C27-mycolipenic) acid, and the second least polar glycolipid contained major amounts of 3-hydroxy-2,4,6-trimethyltetracosanoic (C27-mycolipanolic) acid in addition to these non-hydroxylated acids. The relatively polar pair of glycolipids were analysed together and released mainly straight-chain C16 and C18 acids, C27-mycolipanolic acid, minor amounts of C25- and C27-mycolipenic acids and major proportions of an acid having the chromatographic properties of 2,4-dimethyldocosanoic acid. The most polar pair of glycolipids co-chromatographed with glycolipid antigens previously detected in Mycobacterium bovis BCG.     

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.     

Cell-surface properties of enterotoxigenic and cytotoxic Salmonella enteritidis and Salmonella typhimurium: studies on hemagglutination, cell-surface hydrophobicity, attachment to human intestinal cells and fibronectin-binding

Thirteen Salmonella enteritidis and S. typhimurium strains with smooth or rough colony morphology were investigated for their surface properties based on hemagglutination (HA), hydrophobicity, and fibronectin-binding profiles. The strains showed 5 different patterns of HA which was mannose-sensitive. The rough strains possessed comparatively greater number of fimbriae than the corresponding smooth strains and also attached to human intestinal cells in greater numbers. The Salmonella strains used in this study interacted with fibronectin and its 29-kDa N-terminal fragment to varied extents. These properties may be helpful in broadening the prospective interaction capabilities of Salmonella organisms with the host surfaces.     

Application of an easy and reliable method for sulfolipid-I detection in the study of its distribution in Mycobacterium tuberculosis strains

Sulfolipid-I (SL-I) is a specific Mycobacterium tuberculosis glycolipid that has been involved in the mechanisms of tuberculoid infection. Until now, a limited number of M. tuberculosis strains have been studied to ascertain their SL-I content, mainly due to the laborious techniques of purification used: DEAE-cellulose column chromatography (DEAE) or extensive solvent extractions. We designed a two-dimensional thin layer chromatographic (2D-TLC) system which allows the easy and reliable detection of SL-I in small amounts of M. tuberculosis-free glycolipid extracts without previous purification. A characteristic SL-I signal was clearly identified by a differential cresyl violet metachromatic stain. Seven clinical isolates, M. tuberculosis H(37)Ra, H(37)Rv and Canetti strains were tested by DEAE and the 2D-TLC system. Identical results were found using both methodologies. The 2D-TLC methodology devised could be applied to a large number of strains to ascertain easily the distribution of SL-I in the strains of M. tuberculosis species.     

Structure of a novel sulfate-containing mycobacterial glycolipid.

We described previously the unusual structures of the two major C-mycoside glycopeptidolipids from Mycobacterium fortuitum biovar. peregrinum. More polar glycolipids, potentially more interesting in terms of antigenicity, were also present in the strains. A combination of FAB mass spectrometry, NMR, chemical analyses, and radiolabeling was successfully applied to these glycolipids to arrive at the unexpected and novel structure for the more polar compound. This consisted of the "orthodox" basic structure of the apolar C-mycosides, modified at the alaninol end by the presence of a sulfate group on position 2 of a 3,4-di-O-methylrhamnosyl residue. This novel and second class of sulfate-containing mycobacterial glycolipid may provide a chemical basis for the differentiation and classification of members of the M. fortuitum complex, the main group causing human diseases among the many fast-growing mycobacteria widely distributed in nature.     

Characterization of the specific antigenicity of Mycobacterium fortuitum.

Mycobacterium fortuitum, biovar, fortuitum, the cause of serious skin and soft-tissue infections, can be differentiated from M. fortuitum, biovar. peregrinum, and other rapidly growing opportunistic mycobacteria by the presence of a unique antigenic glycolipid. The glycolipid is among the simplest of the acyl-trehalose-containing lipooligosaccharide class. The application of 1H and 13C NMR, methylation analysis, FAB/MS, and other procedures demonstrated the structure, beta-D-Glcp-(1----6)-2-O-acyl-alpha-D-Glcp-(1 in equilibrium with 1)-3,4,6-tri-O-acyl-alpha-D-Glcp. Thus, practically all environmental mycobacteria, many of them opportunistic pathogens, can be differentiated serologically and chemically on the basis of unique sugar arrangements within a few classes of glycolipids. The simplicity of the structure in M. fortuitum fortuitum combined with the distinct roughness of the parent strain raises the intriguing possibility that it is a spontaneous rough variant of the other mycobacteria with more elaborate glycolipids.     

The glycolipids of the causative agent of tularemia]

Up to 10 glycolipids were detected in F. tularensis with the use of thin-layer chromatographic techniques. These glycolipids were slime antigens of F. tularensis membrane. Attenuated F. tularensis strains were found to have defects in their glycolipid composition: in the vaccine strain glycolipid 8 was replaced by more polar lipid 8-a; the avirulent strain had only two glycolipids, and one of them was not typical for virulent strains. Considering that glycolipids differed from entero-bacterial Vi-antigen in their physical-chemical and biological properties, the suggestion was made that the use of the symbol "Vi" to denote the surface substances of F. tularensis should be abolished.     

Novel type-specific lipooligosaccharides from Mycobacterium tuberculosis

Mycobacterium tuberculosis (strain Canetti) is characterized by the presence of two novel glycolipids of the alkali-labile, trehalose-containing lipooligosaccharide class. Their structures were established by permethylation, partial acid hydrolysis, infrared and high-field NMR spectroscopy, and electron-impact and fast atom bombardment mass spectrometry of the native glycolipids and hydrolysis products. The trehalose substituent is unique in that it is methylated at the 6'-position. The structure of the simpler of the two glycolipids is 2-O-Me-alpha-L-Fucp(1----3)-beta-D-Glcp(1----3)-2-O-Me- alpha-L-Rhap(1----3)-2-O-Me-alpha-L- Rhap(1----3)-beta-D-Glcp(1----3)-4-O-Me-alpha-L-Rhap(1----3) -6-O-Me-alpha-D- Glc. Further glycosylation of the octaglycosyl unit of this nonantigenic glycolipid by an incompletely defined N-acyl derivative of a 4-amino-4,6-dideoxy-Galp residue results in the second, highly antigenic nonasaccharide-containing glycolipid. Application of two-dimensional proton correlation spectroscopy demonstrated that the fatty acyl substituents are located on the 2,3,6 and 3,4,6 hydroxyl groups of the terminal glucosyl unit in the proportions of 2:3. Gas chromatography/mass spectrometry and optical rotation measurement allowed identification of the fatty acyl esters as primarily 2L-, 4L-dimethylhexadecanoate, 2L-,4L-,6L-,8L-tetramethyloctadecanoate, and 2-methyl-3-hydroxyeicosanoate. The relationship of these glycolipids to different morphological forms of M. tuberculosis and to virulence is discussed.     

Location of acyl groups of trehalose-containing lipooligosaccharides of mycobacteria

A variant of a Mycobacterium sp. originating in a patient with Crohn's disease, but not necessarily implicated in the disease, provided a simple version of a newer class of species-specific surface glycolipids, the trehalose-containing lipooligosaccharides. A combination of high-resolution 1H nuclear magnetic resonance, methylation, ethylation, and absolute configurational analysis established the structure of the oligosaccharide unit as beta-D-Glcp(1----3)-alpha-L-Rhap(1----3)-alpha-D-Glcp(1----1)-alph a-D-Glcp (where Glc is glucose, Rha is rhamnose, and p is pyranosyl), and gas chromatography-electron impact mass spectrometry allowed identification of the fatty acyl esters as primarily 2,4-dimethyltetradecanoate. The relative simplicity of the glycolipid combined with the application of a mild methylation procedure and californium-252 plasma desorption mass spectrometry allowed recognition of three such acyl residues on the 3-, 4-, and 6-hydroxyl positions of the terminal glucosyl residue of the trehalose unit. Thus, the glycolipid is decidedly amphipathic yet is clearly not membranous. This observation leads to speculation about the role of these novel lipooligosaccharides in contributing to the outer segment of the hydrophobic barrier of the cell wall of certain mycobacteria.     

Wild Animal Mycobacterial Isolates

Thirteen strains of mycobacteria isolated from deer and various species of wild birds were analysed by gas chromatography (GG) for cellular fatty acids and by thin-layer chromatography (TLG) for polar lipids. These strains were compared to reference strains of Mycobacterium avium, M. para tuberculosis and M. mal-moense. All the examined strains exhibited a generally similar fatty acid pattern characterized by relatively large amounts of hexadenca-noate (16:0), octadecenoate (18:1), octadecanoate (18:0) and 10-me-thyl-octadecanoate (tuberculostearic acid, 10-Me-18:0). Several additional acids were also generally present but in smaller amounts. By means of small but distinct differences in fatty acid composition, the wild animal isolates could be distinguished from both M. paratuber-culosis and M. malmoense but not from M. avium. The TLG polar lipid patterns on the other hand separated the wild animal isolates into 2 distinct groups of complex and simple polar lipid composition which corresponded to the morphologically smooth and rough types, respectively. The complex patterns of the smooth strains were comparable to those of the M. avium serovars whereas both the rough wild animal isolates and all the M. paratuber-culosis strains showed a simple pattern of polar lipids. Both fatty acid profiles and TLG polar lipid patterns support allocation of the wild animal isolates to the MAIS complex. Moreover, the 2 chemical techniques, particularly the GC procedure, are very useful for a more rapid and precise identification of the slow-growing wild animal mycobacterial isolates which have hitherto been characterized on basis of vague criteria.     

Monoglycosyldiacylphenol-phthiocerol of Mycobacterium tuberculosis and Mycobacterium bovis

The structure of a minor glycolipid of M. tuberculosis (strain Canetti) is shown to be 2-O-methyl-alpha-L-rhamnosyldiacylphenol-phthiocerol. A similar compound with non-methylated rhamnose as sugar moiety was also detected. In the course of this work, the structure of mycoside B from Mycobacterium bovis was reexamined, and was shown to be identical to that of the 2-O-methylrhamnosyldiacylphenol-phthiocerol of the Canetti strain, while it was described as a 2-O-methyl-beta-D-rhamnosyl derivative in the literature. This result is in agreement with the known close relationship between M. tuberculosis and M. bovis. Careful examination of chromatographic fractions containing the above mentioned lipids showed that the occurrence of mycoloyl residues in some phenol-phthiocerol glycolipids, postulated in the literature, was likely to be due to the presence of glycerol monomycolate contaminants.     

Polyphthienoyl trehalose, glycolipids specific for virulent strains of the tubercle bacillus

Phthienoic acids constitute a family of dextro-rotary odd-numbered unsaturated fatty acids isolated exclusively from virulent strains of human and bovine tubercle bacilli. In the bacterial cell they are not free and a search for their linked form in complex wall lipids of Mycobacterium tuberculosis (strain Canetti) showed that they esterified trehalose. Structural elucidation of the major phthienoyl trehalose showed the occurrence of five acyl residues located at 2, 2', 3', 4 and 6' positions of trehalose. The acyl substituents were mainly 2,4,6-trimethyl tetracos-2-enoic acid (C27 phthienoic acid) accompanied by its homologs. In addition to these branched fatty acids, straight-chain C16 and C18 acyls composed about 20% of the substituents. The proposed structure is a new one, both for the mycobacterial-specific glycolipid and for the substituted positions on trehalose. Other minor acyl trehaloses were detected in M. tuberculosis (strain Canetti), differing from the major component by the occurrence of an additional hydroxy fatty acid (3-hydroxy-2,4,6-trimethyl tetracosanoic acid) or by the number of acyl substituents. The major glycolipid presented a weak activity in vitro on mitochondrial oxidative phosphorylation. These glycolipids and phthienoic acids could serve as virulence indicators.     

Morphotypic conversion in Listeria monocytogenes biofilm formation: biological significance of rough colony isolates

Adherence to a stainless steel surface selected isolates of Listeria monocytogenes with enhanced surface colonization abilities and a change in phenotype from the common smooth colony morphology to a succession of rough colony morphotypes. Growth in broth culture of the best-adapted, surface-colonizing rough colony morphotype gave a smooth colony revertant. Comparative analysis revealed that the smooth and rough variants had similar phenotypic and biochemical characteristics (e.g., identical growth rates and tolerances to antibiotics and environmental stressors). Rough colony isolates, however, failed to coordinate motility or induce autolysis. The defect in autolysis of rough colony isolates, which involved impaired cellular localization of several peptidoglycan-degrading enzymes, including cell wall hydrolase A (CwhA), suggested a link to a secretory pathway defect. The genetic basis for the impairment was studied at the level of the accessory secretory pathway component SecA2. DNA sequencing of the secA2 gene in smooth and rough colony isolates found no mutations in the coding or promoter regions. Analysis of SecA2 expression with an integrated secA2-FLAG tag construct found the protein to be upregulated in the rough and revertant backgrounds compared to the parental smooth colony isolate. A compensatory mechanism involving the SecA2 secretion pathway components is postulated to control smooth to rough interconversion of L. monocytogenes. Such phenotypic variation may enhance the ability of this opportunistic pathogen to colonize environments as diverse as processing surfaces, food products, and animal hosts.     

Recognition of novel glycolipid antigens from smooth variants of Mycobacterium tuberculosis

A major polar and three minor slightly less polar glycolipids were identified in extracts of two smooth (Canetti) strains of Mycobacterium tuberculosis. Immunostaining on thin-layer chromatograms and enzyme-linked immunosorbent assay (ELISA) of purified lipids demonstrated that the major and the two most polar of the minor glycolipids are potent antigens, reacting with homologous antisera and also with that raised against the type strain (H37Rv).