Motoko Watanabe

Separation and characterization of individual mycolic acids in representative mycobacteria

Total mycolic acid methyl ester fractions were isolated from 24 representatives of Mycobacterium tuberculosis, Mycobacterium bovis (including BCG), Mycobacterium microti, Mycobacterium kansasii and Mycobacterium avium. The total mycolate functional group composition was estimated from (1)H-NMR spectra. Mycolates were separated into alpha-mycolates, methoxymycolates and ketomycolates and each class was further separated by argentation chromatography into mycolates with no double bonds, with one trans-double bond and with one cis-double bond. Mass spectrometry revealed the mycolate chain lengths and (1)H-NMR the cis- and trans-double bond and cyclopropane ring content. The same species had similar mycolate profiles; the major type of each class had cis- or trans-cyclopropane rings and lacked double bonds. Minor proportions of possible unsaturated precursors of the cyclopropane mycolates were commonly encountered. Among unusual alpha-mycolates, many strains had tricyclopropyl components with chains extended by 6 to 8 carbons. Significantly, M. tuberculosis (Canetti) and M. avium had alpha-mycolates with a trans-double bond and cyclopropane ring, whose chain lengths suggested a relationship to possible precursors of oxygenated mycolates. The methoxy- and ketomycolates from a majority of M. tuberculosis strains had minor amounts of components with additional cyclopropane rings, some of whose chains were also extended by 6 to 8 carbons. These latter mycolates were major components in the attenuated M. tuberculosis H37Ra strain, whose mycolate profile was distinct from those of other strains of M. tuberculosis.

Location of functional groups in mycobacterial meromycolate chains; the recognition of new structural principles in mycolic acids.

Mycobacterial alpha-, methoxy- and keto-mycolic acid methyl esters were separated by argentation chromatography into mycolates with no double bond, with one trans double bond or with one cis double bond. Meromycolic acids were prepared from each methyl mycolate fraction by pyrolysis, followed by silver oxide oxidation, and analysed by high-energy collision-induced dissociation/fast atom bombardment MS to reveal the exact locations of the functional groups within the meromycolate chain. The locations of cis and trans double bonds, cis and trans cyclopropane rings, methoxy and keto groups, and methyl branches within the meromycolate chain were determined from their characteristic fragment ion profiles, and the structures of the meromycolic acids, including those with three functional groups extracted from Mycobacterium tuberculosis H37Ra, Mycobacterium bovis BCG and Mycobacterium microti, were established. Meromycolic acids with one cis double bond were structurally closely related to those with one cis cyclopropane ring, whereas the meromycolic acids with one trans cyclopropane ring were closely related to the corresponding meromycolic acids with one cis cyclopropane ring. A close relationship between methoxy- and keto-meromycolic acids was also implied. The relationship between the meromycolic acids with a trans double bond and the other meromycolic acids was not clearly revealed, and they did not appear to be immediate substrates for trans cyclopropanation.

Structural elucidation of new phenolic glycolipids from Mycobaclerium tuberculosis

From one clinical isolate of Mycobacterium tuberculosis, two new phenolic glycolipids(PGLs) were obtained as its major PGLs. These were dimycocerosyl esters of 2,4-di-O-methyl-fucopyranosyl-(alpha 1-->3)-rhamnopyranosyl-(alpha 1-->3)-2-O-methyl-rhamnopyranosyl-(alpha 1-->)-phenolphthiocerol A and -phenolphthiotriol A, which were produced by this strain at a ratio of about 5:1. Another clinical isolate of this species was found to produce PGL-tb1 and its analogue, 2,3,4-tri-O-methyl-fucopyranosyl-(alpha 1-->3)-rhamnopyranosyl-(alpha 1-->3)-2-O-methyl-rhamnopyranosyl-(alpha 1-->)-phenolphthiotriol A at a ratio of about 1:3. The fact that different strains of M. tuberculosis produce chemically different PGLs as their major PGLs may be related to the diversity of virulence of the clinical isolates of M. tuberculosis.

Pathophysiological Implications of Cell Envelope Structure in Mycobacterium tuberculosis and Related Taxa

Mycobacterium tuberculosis has a cell envelope incorporating a peptidoglycan-linked arabinogalactan esterified by long-chain mycolic acids. A range of “free” lipids are associated with the “bound” mycolic acids, producing an effective envelope outer membrane. The distribution of these lipids is discontinuous among mycobacteria and such lipids have proven potential for biomarker use in tracing the evolution of tuberculosis. A plausible evolutionary scenario involves progression from an environmental organism, such as Mycobacterium kansasii, through intermediate “smooth” tubercle bacilli, labelled “Mycobacterium canettii”; cell envelope lipid composition possibly correlates with such a progression. M. kansasii and “M. canettii” have characteristic lipooligosaccharides, associated with motility and biofilms, and glycosyl phenolphthiocerol dimycocerosates (“phenolic glycolipids”). Both these lipid classes are absent in modern M. tuberculosis sensu stricto, though simplified phenolic glycolipids remain in certain current biotypes. Dimycocerosates of the phthiocerol family are restricted to smaller phthiodiolone diesters in M. kansasii. Diacyl and pentaacyl trehaloses are present in “M. canettii” and M. tuberculosis, where they are accompanied by related sulfated acyl trehaloses. In comparison with environmental mycobacteria, subtle modifications in mycolic acid structures in “M. canettii” and M. tuberculosis are notable. The probability of essential tuberculosis evolution taking place in Pleistocene megafauna, rather than Homo sapiens, is reemphasised.

Differential conformational behaviors of α-mycolic acids in Langmuir monolayers and computer simulations

Phase diagrams of Langmuir monolayers of alpha-mycolic acids (alpha-MAs) from representative slow growing mycobacteria were intensively analyzed over a range of temperatures, by using so-called type-1 alpha-MAs having two cis-cyclopropyl groups from Mycobacterium tuberculosis, Mycobacterium kansasii and Mycobacterium avium-intracellulare complex (MAC) and type-3 alpha-MA, having one cis-cyclopropyl and one cis-double bond from Mycobacterium bovis BCG and MAC. Their intrachain groups are either cis-cyclopropyl or cis-double bond but the methylene chain segment lengths vary greatly. However, their monolayer features were alike: at lower temperatures and surface pressures, the molecules seemed to be in folded conformations, requiring larger mean molecular areas, whereas at higher temperatures and surface pressures, to be in extended conformations, requiring smaller average molecular areas approximately equivalent to cross sectional area of two hydrocarbon chains in a condensed film. In phase diagrams, the region for the folded forms of alpha-MAs was very limited, in contrast to the previously established behavior of ketomycolates, where complete folding predominated. Easy conversion of folded to extended conformations was indicated by thermodynamic studies of the Langmuir monolayer results and computer simulations.