Philip Draper

The Envelope Layers of Mycobacteria with Reference to their Pathogenicity

The review discusses current knowledge of the biosynthesis, composition and arrangement of the mycobacterial envelope, describes the biological activities of the constituents and considers how these activities may be relevant to the pathology of mycobacterial disease. The envelope possesses three structural components: plasma membrane, wall and capsule. Although the major biomolecules occurring in each of these parts are known, the distribution of numerous minor substances is poorly understood; an attempt has been made to assign them to particular positions on rational grounds. The plasma membrane appears to be a typical bacterial membrane but, though vital to the mycobacterium, probably plays little part in pathological processes. The wall partly resembles a Gram-positive wall, but is unusual in having a layer of lipid (mycolate esters) which is probably arranged to form a permeability barrier to polar molecules. The capsule, whose chemical composition has only recently been recognized, consists of polysaccharide and protein with traces of lipid; the arrangement of these components is imperfectly understood. Constituents of all parts of the envelope have biological activities which may be relevant. The likely importance of these activities in the overall effect of the envelope is considered.

Mechanisms of pyrazinamide resistance in mycobacteria: importance of lack of uptake in addition to lack of pyrazinamidase activity.

Mycobacteria are known to acquire resistance to the antituberculous drug pyrazinamide (PZA) through mutations in the gene encoding pyrazinamidase (PZase), an enzyme that converts PZA into pyrazinoic acid, the presumed active form of PZA against bacteria. Additional mechanisms of resistance to the drug are known to exist but have not been fully investigated. Among these is the non-uptake of the pro-drug, a possibility investigated in the present study. The uptake mechanism of PZA, a requisite step for the activation of the pro-drug, was studied in Mycobacterium tuberculosis. The incorporation of [14C]PZA by the bacilli was followed in both neutral and acidic environments since PZA activity is known to be optimal at acidic pH. By using a protonophore (carbonyl cyanide m-chlorophenylhydrazone; CCCP), valinomycin, arsenate and low temperature, it was shown that an ATP-dependent transport system is involved in the uptake of PZA. Whilst the structurally analogous compound nicotinamide inhibited the transport system of PZA, other structurally related compounds such as pyrazinoic acid, isoniazid and cytosine did not. Acidic conditions were also without effect. Based on diffusion experiments in liposomes, it was found that PZA diffuses rapidly through membrane bilayers, faster than glycerol, whilst the presence of OmpATb, the porin-like protein of M. tuberculosis, in proteoliposomes slightly increased the diffusion of the drug. This finding may explain why the cell wall mycolate hydrophobic layer does not represent the limiting step in the diffusion of PZA, as judged from comparative experiments using a M. tuberculosis strain and its isogenic mutant elaborating 40% less covalently linked mycolates. PZase activity, and PZA uptake and susceptibility in different mycobacterial species were compared. M. tuberculosis, a naturally PZA-susceptible species, was the only species that exhibited both PZase activity and PZA uptake; no such correlation was observed with the four naturally resistant species examined. Mycobacterium smegmatis possessed a functional PZase but did not take up PZA; the reverse was true for the PZase-negative strain of Mycobacterium avium used, with PZA uptake comparable to that of M. tuberculosis. Mycobacterium bovis BCG and Mycobacterium kansasii exhibited neither a PZase activity nor PZA uptake. These data clearly demonstrate that one of the mechanisms of resistance to PZA resides in the failure of strains to take up the drug, indicating that susceptibility to PZA in mycobacteria requires both the presence of a functional PZase and a PZA transport system. No correlation was observed between the occurrence and cellular location of PZase and of nicotinamidase in the strains examined, suggesting that one or both amides can be hydrolysed by other mycobacterial amidases.

The functions of OmpATb, a pore-forming protein of Mycobacterium tuberculosis

The functions of OmpATb, the product of the ompATb gene of Mycobacterium tuberculosis and a putative porin, were investigated by studying a mutant with a targeted deletion of the gene, and by observing expression of the gene in wild‐type M. tuberculosis H37Rv by real‐time polymerase chain reaction (PCR) and immunoblotting. The loss of ompATb had no effect on growth under normal conditions, but caused a major reduction in ability to grow at reduced pH. The gene was substantially upregulated in wild‐type bacteria exposed to these conditions. The mutant was impaired in its ability to grow in macrophages and in normal mice, although it was as virulent as the wild type in mice that lack T cells. Deletion of the ompATb gene reduced permeability to several small water‐soluble substances. This was particularly evident at pH 5.5; at this pH, uptake of serine was minimal, suggesting that, at this pH, OmpATb might be the only functioning porin. These data indicate that OmpATb has two functions: as a pore‐forming protein with properties of a porin, and in enabling M. tuberculosis to respond to reduced environmental pH. It is not known whether this second function is related to the porin‐like activity at low pH or involves a completely separate role for OmpATB. The involvement with pH is likely to contribute to the ability of M. tuberculosis to overcome host defence mechanisms and grow in a mammalian host.

The nature of the electron-transparent zone that surrounds Mycobacterium lepraemurium inside host cells.

SUMMARY: Liver and spleen tissue from mice infected 4 to 5 months previously with Mycobacterium lepraemurium has been examined in the electron microscope by negative staining, freeze-etching and ultrathin sectioning. Part or all of the electron-transparent zone seen around sectioned bacteria is composed of parallel fibrils wrapped longitudinally around the bacteria. It was isolated from homogenates of infected livers and spleens using urea density gradients and contained a mycoside of type C, a peptidoglycolipid known to occur in some other species of mycobacteria. The mycoside therefore forms a capsule around the bacterium to protect and insulate it from the host cell and its lysosomes.

pH-dependent pore-forming activity of OmpATb from Mycobacterium tuberculosis and characterization of the channel by peptidic dissection

Mycobacteria are characterized by an unusual cell wall that controls nutrient and small hydrophilic compound permeability. Porin‐like proteins are necessary to ensure the transport of molecules into the cell. Here, we investigated the pore‐forming properties of OmpATb, a porin from Mycobacterium tuberculosis, in lipid bilayers. Multi‐channel experiments showed an asymmetric behaviour with channel closures at negative critical voltages (Vc) and a strong decrease in Vc at acidic pH. Single‐channel experiments gave conductance values of about 850 ± 80 pS in 1 M KCl and displayed a weak cationic selectivity in 4–8 pH range. The production and characterization of a series of truncated OmpATb proteins, showed that the central domain (OmpATb73−220) was sufficient to induce the ion channel properties of the native protein in lipid bilayers, i.e. asymmetric insertion, pH‐dependent voltage closure, cationic selectivity and similar conductance values in 1 M KCl. Western blot analysis suggests that the presence of OmpATb is only restricted to certain pathogenic species. Therefore, the propensity of channels of native OmpATb to close at low pH may represent an intrinsic property allowing pathogenic mycobacteria to adapt and survive to mildly acidic conditions, such as those encountered within the macrophage phagosome.

Quantitative comparison of the mycolic and fatty acid compositions of Mycobacterium leprae and Mycobacterium gordonae

The mycolic and fatty acids of three samples each of Mycobacterium leprae and Mycobacterium gordonae were compared. Acids released by whole-organism alkaline hydrolysis were converted to 4-nitrobenzyl esters and mycolic acids were further derivatized to t-butyldimethylsilyl ethers. Thin-layer chromatography of the derivatized long-chain extracts showed that all three M. leprae preparations contained so-called alpha-mycolates and ketomycolates but that the M. gordonae samples had a methoxymycolate in addition to the above types. Silica gel normal-phase high-performance liquid chromatography of the total mycolic acid derivatives confirmed the lack of detectable amounts of methoxymycolates in M. leprae and reverse-phase chromatography of the individual mycolate types demonstrated the homogeneity of the chain lengths of the mycolic acids in each species. Non-hydroxylated fatty acid 4-nitrobenzyl esters were transformed to methyl esters and examined by gas chromatography. Tuberculostearic (10-methyloctadecanoic) acid was a major component of the lipids of all three M. leprae preparations but it was absent in one M. gordonae strain and a very minor component in the other representatives of this latter species. On the basis of fatty and mycolic acid compositions, therefore, a previously suggested close relationship between M. leprae and M. gordonae was not supported.

Isolation of a Characteristic Phthiocerol Dimycocerosate from Mycobacterium leprae

A characteristic mycobacterial wax, phthiocerol dimycocerosate, has been isolated from liver of armadillos experimentally infected with Mycobacterium leprae. The structure of this wax is generally similar to that produced by Mycobacterium tuberculosis, but the homologous phthiocerol and the mycocerosic acid components from M. leprae are significantly different from those of M. tuberculosis.

Novel O-Methylated Terminal Glucuronic Acid Characterizes the Polar Glycopeptidolipids of Mycobacterium habana Strain TMC 5135

Mycobacterium “habana” strain TMC 5135, which has been proposed as a vaccine against both leprosy and tuberculosis, is considered to be a strain of serotype I of the recognized species Mycobacterium simiae. We have now shown that each of these strains possesses characteristic polar glycopeptidolipids (GPL) which are sufficiently different to allow unequivocal strain identification. Thin layer chromatographic analysis demonstrated that M. habana synthesizes a family of apolar GPLs and three distinct polar GPLs (pGPL-I to -III) which exhibited migration patterns different from those of M. simiae serotype I (pGPL-Sim). Using a combination of chemical, mass spectrometric, and proton-NMR analyses, the GPLs from M. habana were determined to be based on the same generic structure as those from the M. avium complex, namely N-fatty acyl-D-Phe-(O-saccharide)-D-allo-Thr-D-Ala-L-alaninyl-O-monosaccharide. The de-O-acetylated apolar GPLs contain a 3-O-Me-6-deoxy-Tal attached to the allo-Thr and either a 3-O-Me-Rha or a 3,4-di-O-Me-Rha attached to the alaninol. In the pGPLs, oligosaccharides were found to be attached to the allo-Thr. The oligoglycosyl alditol reductively released from the least polar pGPL-I was fully characterized as L-Fucpα13-(6-O-Me)-D-Glcpβ13-(4-O-Me)-L-Rhapα13-L-Rhapα12-(3-O-Me)-6-deoxy-Tal. In pGPLII and -III, the terminal Fuc residue is further 3-O-methylated and 4-O-substituted with an additional 2,4-di-O-Me-D-GlcA and 4-O-Me-D-GlcA, respectively. The corresponding oligosaccharide from pGPL-Sim was shown to be of identical molecular weight to pGPL-II but terminating with a 3,4-di-O-Me-GlcA. Enzyme-linked immunosorbent assay-based serological studies using anti-M. habana and anti-M. simiae sera against whole cells and purified pGPLs firmly established the polar GPLs as important antigens and indicated that the terminal epitopes L-Fuc-, 2,4-di-O-Me-D-GlcA, and 4-O-Me-D-GlcA uniquely present in pGPL-I, -II, and -III, respectively, confer sufficient specificity for the identification of M. habana as a distinct serotype of M. simiae.

The free lipids of Mycobacterium leprae harvested from experimentally infected nine-banded armadillos.

The free lipids of a sample of Mycobacterium leprae were extracted by a procedure designed to produce separate non-polar and polar fractions. The composition of these lipids was analysed semi-quantitatively by five special thin-layer chromatographic systems covering the total range of mycobacterial lipid polarities. In order of increasing polarity, the major lipids were dimycocerosates of phthiocerol A, phthiocerol B and phthiodiolone A, glycosyl phenolphthiocerol dimycocerosates and phospholipids, including monoacylphosphatidylinositol di- and pentamannosides. The diacylated forms of these latter lipids, found in most mycobacteria, were not present. The composition of the free lipids of the leprosy bacillus, surveyed over the total polarity range for the first time, showed that the patterns were particularly related to those of Mycobacterium bovis, Mycobacterium kansasii and Mycobacterium marinum.

Lipid biochemistry takes a stand against tuberculosis.

Although several excellent drugs are available to treat tuberculosis, their mechanisms are not well understood. Identification of the target of the tuberculosis drug pyrazinamide underscores the role that lipids play in disease pathogenesis, and reveals new avenues for drug design (pages 1043–1047).