Arabinan-deficient mutants of Corynebacterium glutamicum and the consequent flux in decaprenylmonophosphoryl-D-arabinose metabolism

The arabinogalactan (AG) of Corynebacterianeae is a critical macromolecule that tethers mycolic acids to peptidoglycan, thus forming a highly impermeable cell wall matrix termed the mycolyl-arabinogalactan peptidoglycan complex (mAGP). The front line anti-tuberculosis drug, ethambutol (Emb), targets the Mycobacterium tuberculosis and Corynebacterium glutamicum arabinofuranosyltransferase Mt-EmbA, Mt-EmbB and Cg-Emb enzymes, respectively, which are responsible for the biosynthesis of the arabinan domain of AG. The substrate utilized by these important glycosyltransferases, decaprenylmonophosphoryl-D-arabinose (DPA), is synthesized via a decaprenylphosphoryl-5-phosphoribose (DPPR) synthase (UbiA), which catalyzes the transfer of 5-phospho-ribofuranose-pyrophosphate (pRpp) to decaprenol phosphate to form DPPR. Glycosyl compositional analysis of cell walls extracted from a C. glutamicum::ubiA mutant revealed a galactan core consisting of alternating beta(1-->5)-Galf and beta(1-->6)-Galf residues, completely devoid of arabinan and a concomitant loss of cell-wall-bound mycolic acids. In addition, in vitro assays demonstrated a complete loss of arabinofuranosyltransferase activity and DPA biosynthesis in the C. glutamicum::ubiA mutant when supplemented with p[14C]Rpp, the precursor of DPA. Interestingly, in vitro arabinofuranosyltransferase activity was restored in the C. glutamicum::ubiA mutant when supplemented with exogenous DP[14C]A substrate, and C. glutamicum strains deficient in ubiA, emb, and aftA all exhibited different levels of DPA biosynthesis.     

Topology and mutational analysis of the single Emb arabinofuranosyltransferase of Corynebacterium glutamicum as a model of Emb proteins of Mycobacterium tuberculosis

The cell wall mycolyl-arabinogalactan (AG)--peptidoglycan complex is essential in mycobacterial species, such as Mycobacterium tuberculosis, and is the target of several antitubercular drugs. For instance, ethambutol (EMB) targets AG biosynthesis through inhibition of the arabinofuranosyltransferases Mt-EmbA and Mt-EmbB, as well as the single Emb from Corynebacterium glutamicum. Here, we present for the first time an experimental analysis of the membrane topology of Emb. The domain organization clearly positions highly conserved loop regions, like the recognized glycosyltransferase C motif and the hydrophilic C-terminus towards the periplasmic side of the cell. Moreover, the assignment and orientation of hydrophobic segments identified a loop region, which might dip into the membrane and could possibly line a transportation channel for the emerging substrate. Site-directed mutations introduced into plasmid-encoded Cg-emb were analyzed in a C. glutamicumDeltaemb strain for their AG glycosyl composition and linkage analysis. Mutations analyzed did not perturb galactan synthesis; however, D297A produced a dramatically reduced arabinan content and prevented growth, indicating an inactive Emb. A second D298A mutation also drastically reduced arabinan content; however, growth of the corresponding mutant was not altered, indicating a certain tolerance of this mutation in terms of Emb function. A W659L-P667A-Q674E triple mutation in the chain length regulation motif (Pro-motif) resulted in a reduced arabinose deposition in AG but retained all arabinofuranosyl linkages. Taken together, the data clearly define important residues of Emb involved in arabinan domain formation and, for the first time, shed new light on the topology of this important enzyme.     

Identification of a novel arabinofuranosyltransferase (AftA) involved in cell wall arabinan biosynthesis in Mycobacterium tuberculosis

The cell wall mycolyl-arabinogalactan-peptidoglycan complex is essential in mycobacterial species, such as Mycobacterium tuberculosis, and is the target of several anti-tubercular drugs. For instance, ethambutol targets arabinogalactan biosynthesis through inhibition of the arabinofuranosyltransferases Mt-EmbA and Mt-EmbB. Following a detailed bioinformatics analysis of genes surrounding the conserved emb locus, we present the identification and characterization of a novel arabinofuranosyltransferase AftA (Rv3792). The enzyme catalyzes the addition of the first key arabinofuranosyl residue from the sugar donor beta-D-arabinofuranosyl-1-monophosphoryldecaprenol to the galactan domain of the cell wall, thus "priming" the galactan for further elaboration by the arabinofuranosyltransferases. Because aftA is an essential gene in M. tuberculosis, we deleted its orthologue in Corynebacterium glutamicum to produce a slow growing but viable mutant. Analysis of its cell wall revealed the complete absence of arabinose resulting in a truncated cell wall structure possessing only a galactan core with a concomitant loss of cell wall-bound mycolates. Complementation of the mutant was fully restored to the wild type phenotype by Cg-aftA. In addition, by developing an in vitro assay using recombinant Escherichia coli expressing Mt-aftA and use of cell wall galactan as an acceptor, we demonstrated the transfer of arabinose from beta-D-arabinofuranosyl-1-monophosphoryldecaprenol to galactan, and unlike the Mt-Emb proteins, Mt-AftA was not inhibited by ethambutol. This newly discovered glycosyltransferase represents an attractive drug target for further exploitation by chemotherapeutic intervention.     

Detailed structural and quantitative analysis reveals the spatial organization of the cell walls of in vivo grown Mycobacterium leprae and in vitro grown Mycobacterium tuberculosis

The cell wall of mycobacteria consists of an outer membrane, analogous to that of gram-negative bacteria, attached to the peptidoglycan (PG) via a connecting polysaccharide arabinogalactan (AG). Although the primary structure of these components is fairly well deciphered, issues such as the coverage of the PG layer by covalently attached mycolates in the outer membrane and the spatial details of the mycolic acid attachment to the arabinan have remained unknown. It is also not understood how these components work together to lead to the classical acid-fast staining of mycobacteria. Because the majority of Mycobacterium tuberculosis bacteria in established experimental animal infections are acid-fast negative, clearly cell wall changes are occurring. To address both the spatial properties of mycobacterial cell walls and to begin to study the differences between bacteria grown in animals and cultures, the cell walls of Mycobacterium leprae grown in armadillos was characterized and compared with that of M. tuberculosis grown in culture. Most fundamentally, it was determined that the cell wall of M. leprae contained significantly more mycolic acids attached to PG than that of in vitro grown M. tuberculosis (mycolate:PG ratios of 21:10 versus 16:10, respectively). In keeping with this difference, more arabinogalactan (AG) molecules, linking the mycolic acids to PG, were found. Differences in the structures of the AG were also found; the AG of M. leprae is smaller than that of M. tuberculosis, although the same basic structural motifs are retained.     

Biosynthesis of mycobacterial arabinogalactan: identification of a novel alpha(1-->3) arabinofuranosyltransferase

The cell wall mycolyl-arabinogalactan–peptidoglycan complex is essential in mycobacterial species, such as Mycobacterium tuberculosis and is the target of several antitubercular drugs. For instance, ethambutol targets arabinogalactan biosynthesis through inhibition of the arabinofuranosyltransferases Mt-EmbA and Mt-EmbB. A bioinformatics approach identified putative integral membrane proteins, MSMEG2785 in Mycobacterium smegmatis , Rv2673 in Mycobacterium tuberculosis and NCgl1822 in Corynebacterium glutamicum , with 10 predicted transmembrane domains and a glycosyltransferase motif (DDX), features that are common to the GT-C superfamily of glycosyltransferases. Deletion of M. smegmatis MSMEG2785 resulted in altered growth and glycosyl linkage analysis revealed the absence of AG α(1→3)-linked arabinofuranosyl (Ara f ) residues. Complementation of the M. smegmatis deletion mutant was fully restored to a wild-type phenotype by MSMEG2785 and Rv2673, and as a result, we have now termed this previously uncharacterized open reading frame, a rabino f uranosyl t ransferase C ( aftC ). Enzyme assays using the sugar donor β- d -arabinofuranosyl-1-monophosphoryl-decaprenol (DPA) and a newly synthesized linear α(1→5)-linked Ara₅ neoglycolipid acceptor together with chemical identification of products formed, clearly identified AftC as a branching α(1→3) arabinofuranosyltransferase. This newly discovered glycosyltransferase sheds further light on the complexities of Mycobacterium cell wall biosynthesis, such as in M. tuberculosis and related species and represents a potential new drug target.     

Identification of a novel arabinofuranosyltransferase AftB involved in a terminal step of cell wall arabinan biosynthesis in Corynebacterianeae, such as Corynebacterium glutamicum and Mycobacterium tuberculosis

Arabinofuranosyltransferase enzymes, such as EmbA, EmbB, and AftA, play pivotal roles in the biosynthesis of arabinogalactan, and the anti-tuberculosis agent ethambutol (EMB) targets arabinogalactan biosynthesis through inhibition of Mt-EmbA and Mt-EmbB. Herein, we describe the identification and characterization of a novel arabinofuranosyltransferase, now termed AftB (Rv3805c), which is essential in Mycobacterium tuberculosis. Deletion of its orthologue NCgl2780 in the closely related species Corynebacterium glutamicum resulted in a viable mutant. Analysis of the cell wall-associated lipids from the deletion mutant revealed a decreased abundance of cell wall-bound mycolic acids, consistent with a partial loss of mycolylation sites. Subsequent glycosyl linkage analysis of arabinogalactan also revealed the complete absence of terminal beta(1 --> 2)-linked arabinofuranosyl residues. The deletion mutant biochemical phenotype was fully complemented by either Mt-AftB or Cg-AftB, but not with muteins of Mt-AftB, where the two adjacent aspartic acid residues, which have been suggested to be involved in glycosyltransferase activity, were replaced by alanine. In addition, the use of C. glutamicum and C. glutamicumDeltaaftB in an in vitro assay utilizing the sugar donor beta-D-arabinofuranosyl-1-monophosphoryl-decaprenol together with the neoglycolipid acceptor alpha-D-Araf-(1 --> 5)-alpha-D-Araf-O-C(8) as a substrate confirmed AftB as a terminal beta(1 --> 2) arabinofuranosyltransferase, which was also insensitive to EMB. Altogether, these studies have shed further light on the complexities of Corynebacterianeae cell wall biosynthesis, and Mt-AftB represents a potential new drug target.     

Elucidation of a protein-protein interaction network involved in Corynebacterium glutamicum cell wall biosynthesis as determined by bacterial two-hybrid analysis

Mycobacterium species have a highly complex and unique cell wall that consists of a large macromolecular structure termed the mycolyl-arabinogalactan-peptidoglycan (mAGP) complex. This complex is essential for growth, survival and virulence of the human pathogen Mycobacterium tuberculosis, and is the target of several anti-tubercular drugs. The closely related species Corynebacterium glutamicum has proven useful in the study of orthologous M. tuberculosis genes and proteins involved in mAGP synthesis. This study examines the construction of a protein-protein interaction network for the major cell wall component arabinogalactan in C. glutamicum based on the use of a bacterial two-hybrid system. We have identified twenty-four putative homotypic and heterotypic protein interactions in vivo. Our results demonstrate an association between glycosyltransferases, GlfT1 and AftB, and interaction between the sub-units of decaprenylphosphoribose epimerase, DprE1 and DprE2. These analyses have also shown that AftB interacts with AftA, which catalyzes the addition of the first three arabinose units onto the galactan chain. Both AftA and AftB associate with other arabinofuranosyltransferases, including Emb and AftC, that elongate and branch the arabinan domain. Moreover, a number of proteins involved in arabinogalactan biosynthesis were shown to form dimers or multimers. These findings provide a useful recourse for understanding the biosynthesis and function of the mycobacterial cell wall, as well as providing new therapeutic targets.     

The Emb proteins of mycobacteria direct arabinosylation of lipoarabinomannan and arabinogalactan via an N-terminal recognition region and a C-terminal synthetic region

The arabinans of the mycobacterial cell wall are key structural and immunological polymers in the context of arabinogalactan (AG) and lipoarabinomannan (LAM) respectively. The three homologous membrane proteins EmbA, EmbB and EmbC are known to be involved in the synthesis of arabinan but their biochemical functions are not understood. Herein we show, that synthesis of LAM, but not AG, ceases after inactivation of embC in Mycobacterium smegmatis by insertional mutagenesis. LAM synthesis is restored upon complementation with the embC wild-type gene. Previously we have shown that the synthesis of the arabinan of AG is affected by embA or embB disruption. Thus the Emb proteins are capable of differential recognition of the galactan or mannan acceptors prior to appropriate arabinosylation. In addition, a combination of genetic and biochemical approaches have allowed us to assign some specific functions to the regions of emb gene products. Complementation of the embCmacr; mutant with a hybrid gene encoding the N-terminus of EmbC and the C-terminus of EmbB resulted in LAM with a lower molecular weight than the wild-type LAM. Structural studies involving enzyme digestion, chromatography and mass spectrometry analyses revealed that the arabinan of the 'LAM' formed in the hybrid was of AG kind rather than LAM type of arabinan.     

Biochemical characterization of the Mycobacterium tuberculosis phosphoribosyl-1-pyrophosphate synthetase

Mycobacterium tuberculosis arabinogalactan (AG) is an essential cell wall component. It provides a molecular framework serving to connect peptidoglycan to the outer mycolic acid layer. The biosynthesis of the arabinan domains of AG and lipoarabinomannan (LAM) occurs via a combination of membrane bound arabinofuranosyltransferases, all of which utilize decaprenol-1-monophosphorabinose as a substrate. The source of arabinose ultimately destined for deposition into cell wall AG or LAM originates exclusively from phosphoribosyl-1-pyrophosphate (pRpp), a central metabolite which is also required for other essential metabolic processes, such as de novo purine and pyrimidine biosyntheses. In M. tuberculosis, a single pRpp synthetase enzyme (Mt-PrsA) is solely responsible for the generation of pRpp, by catalyzing the transfer of pyrophosphate from ATP to the C1 hydroxyl position of ribose-5-phosphate. Here, we report a detailed biochemical and biophysical study of Mt-PrsA, which exhibits the most rapid enzyme kinetics reported for a pRpp synthetase.     

Identification of channel-forming activity in the cell wall of Corynebacterium glutamicum.

The cell wall of the gram-positive Corynebacterium glutamicum was prepared. It contained an ion-permeable channel with a single-channel conductance of about 6 nS in 1 M KCl. The mobility sequence of the ions in the channel is similar to that in the aqueous phase, suggesting that it is a water-filled channel wide enough to allow unhindered diffusion of ions. The results indicate that we have identified the hydrophilic pathway through the mycolic acid layer of C. glutamicum.     

Variation in mannose-capped terminal arabinan motifs of lipoarabinomannans from clinical isolates of Mycobacterium tuberculosis and Mycobacterium avium complex

The unique terminal arabinan motifs of mycobacterial lipoarabinomannan (LAM), which are mannose-capped to different extents, probably constitute the single most important structural entity engaged in receptor binding and subsequent immunopathogenesis. We have developed a concerted approach of endoarabinanase digestion coupled with chromatography and mass spectrometry analysis to rapidly identify and quantitatively map the complement of such terminal units among the clinical isolates of different virulence and drug resistance profiles. In comparison with LAM from laboratory strains of Mycobacterium tuberculosis, an ethambutol (Emb) resistant clinical isolate was shown to have a significantly higher proportion of nonmannose capped arabinan termini. More drastically, the mannose capping was completely inhibited when an Emb-susceptible strain was grown in the presence of subminimal inhibitory concentration of Emb. Both cases resulted in an increase of arabinose to mannose ratio in the overall glycosyl composition of LAM. Emb, therefore, not only could affect the complete elaboration of the arabinan as found previously for LAM from Mycobacterium smegmatis resistant mutant but also could inhibit the extent of mannose capping and hence its associated biological functions in M. tuberculosis. Unexpectedly, an intrinsically Emb-resistant Mycobacterium avium isolate of smooth transparent colony morphology was found to have most of its arabinan termini capped with a single mannose residue instead of the more common dimannoside as established for LAM from M. tuberculosis. This is the first report on the LAM structure from M. avium complex, an increasingly important opportunistic infectious agent afflicting AIDS patients.     

Construction, molecular modeling, and simulation of Mycobacterium tuberculosis cell walls

The mycobacterial cell wall is extraordinarily thick and tight consisting mainly of (1). long chain fatty acids, the mycolic acids, and (2). a unique polysaccharide, arabinogalactan (AG). These two chemical constituents are covalently linked through ester bonds. Minnikin (The Biology of the Mycobacteria; Academic: London, 1982) proposed that the mycobacterial cell wall is composed of an asymmetric lipid bilayer. The inner leaflet of the cell wall contains mycolic acids covalently linked to AG. This inner leaflet is believed to have the lowest permeability to organic compounds of the overall cell wall. Conformational search and molecular dynamics simulation were used to explore the conformational profile of AG and the conformations and structural organization of the mycolic acid-AG complex, and overall, an inner leaflet molecular model of the cell wall was constructed. The terminal arabinose residues of AG that serve as linkers between AG and mycolic acids were found to exist in four major chemical configurations. The mycolate hydrocarbon chains were determined to be tightly packed and perpendicular to the "plane" formed by the oxygen atoms of the 5-hydroxyl groups of the terminal arabinose residues. For Mycobacterium tuberculosis, the average packing distance between mycolic acids is estimated to be approximately 7.3 A. Thus, Minnikin's model is supported by this computational study. Overall, this modeling and simulation approach provides a way to probe the mechanism of low permeability of the cell wall and the intrinsic drug resistance of M. tuberculosis. In addition, monolayer models were built for both dipalmitoylphosphatidylethanolamine and dimyristoylphosphatidylcholine, two common phospholipids in bacterial and animal membranes, respectively. Structural comparisons of these cell wall phospholipid membrane models were made to the M. tuberculosis cell wall model.     

Identification of a Terminal Rhamnopyranosyltransferase (RptA) Involved in Corynebacterium glutamicum Cell Wall Biosynthesis

A bioinformatics approach identified a putative integral membrane protein, NCgl0543, in Corynebacterium glutamicum, with 13 predicted transmembrane domains and a glycosyltransferase motif (RXXDE), features that are common to the glycosyltransferase C superfamily of glycosyltransferases. The deletion of C. glutamicum NCgl0543 resulted in a viable mutant. Further glycosyl linkage analyses of the mycolyl-arabinogalactan-peptidoglycan complex revealed a reduction of terminal rhamnopyranosyl-linked residues and, as a result, a corresponding loss of branched 2,5-linked arabinofuranosyl residues, which was fully restored upon the complementation of the deletion mutant by NCgl0543. As a result, we have now termed this previously uncharacterized open reading frame, rhamnopyranosyltransferase A (rptA). Furthermore, an analysis of base-stable extractable lipids from C. glutamicum revealed the presence of decaprenyl-monophosphorylrhamnose, a putative substrate for the cognate cell wall transferase.A common feature of members of the Corynebacterineae is that they possess an unusual cell wall dominated by a heteropolysaccharide termed an arabinogalactan (AG), which is linked to both mycolic acids and peptidoglycan, forming the mycolyl-arabinogalactan-peptidoglycan (mAGP) complex (5, 10, 12, 15, 24, 25, 34). The formation of the arabinan domain in the mAGP complex, consisting mainly of α1→5, α1→3, and β1→2 glycosyl linkages, results from the subsequent addition of arabinofuranose (Araf) from the lipid-linked sugar donor β-d-arabinofuranosyl-1-monophosphoryldecaprenol (DPA) by a set of unique membrane-bound arabinofuranosyltransferases (5, 7, 12, 18, 34).The deletion of Corynebacterium glutamicum emb (emb_Cg) (4) and a chemical analysis of the cell wall revealed a novel truncated AG structure possessing only terminal Araf residues with a corresponding loss of cell wall-bound mycolic acids (4). The presence of a novel enzyme responsible for “priming” the galactan domain for further elaboration by Emb_Cg proteins led to the identification of AftA, which belongs to the glycosyltransferase C (GT-C) superfamily (5). Recently, additional GT-C enzymes have been identified, termed AftB, which is responsible for the attachment of terminal β(1→2) Araf residues (34), and AftC, which is involved in AG branching (12) before decoration with mycolic acids, both of which are conserved within the Corynebacterineae (12, 34). It is clear that additional glycosyltransferases involved in both AG and lipoarabinomannan biosynthesis still remain to be identified. Indeed, Liu and Mushegian (22) identified 15 members of the GT-C superfamily residing in the Corynebacterineae, representing candidates involved in the biosynthesis of cell wall-related glycans and lipoglycans (22). We have continued our earlier studies (5, 12, 34) to identify genes required for the biosynthesis of the core structural elements of the mAGP complex by studying mutants of C. glutamicum and the orthologous genes and enzymes of Mycobacterium tuberculosis.A particularly interesting feature of C. glutamicum is the presence of terminal rhamnopyranose (t-Rhap) residues attached to the C2 position of α(1→5)-linked Araf residues in the arabinan domain of AG (4). The biological function of these residues remains to be clarified; nevertheless, they are a feature of the corynebacterial cell wall, and the biosynthesis of which needs to be addressed. The current paradigm of AG biosynthesis follows a linear pathway which is built upon a decaprenyl pyrophosphate lipid carrier. The unique disaccharide linker and galactan domain is synthesized by a variety of GT-A and GT-B family glycosyltransferases, all of which utilizing a nucleotide diphosphate-activated sugar substrate for transferase activity. It has been hypothesized by us (3, 5) and others (8) that a major shift in the biosynthetic machinery takes place upon the initiation of arabinan polymerization. AftA, Emb, AftC, and AftB all belong to the GT-C family of glycosyltransferases, all of which utilize DPA as the sole lipid-activated phosphosugar donor for arabinose transfer into the cell wall. Since t-Rhap residues are present in the arabinan component of the cell wall, the enzyme(s) responsible for its addition is likely to belong to the GT-C family of glycosyltransferases and, as determined through deduction, is one which utilizes a lipid-phosphate-derived rhamnose substrate similar to DPA. Herein, we present the putative protein NCgl0543 as a distinct t-Rhap of the GT-C superfamily, which is responsible for the transfer of t-Rhap residues to the arabinan domain to form the branched 2,5-linked Araf motifs of C. glutamicum. In addition, we have identified a novel decaprenyl-monophosphorylrhamnose and discuss its role in substrate presentation for AG biosynthesis in C. glutamicum.     

The role of the embA and embB gene products in the biosynthesis of the terminal hexaarabinofuranosyl motif of Mycobacterium smegmatis arabinogalactan.

The emb genes are conserved among different mycobacteria. In Mycobacterium smegmatis and Mycobacterium tuberculosis, they belong to an operon comprising three genes, embC, embA, and embB. The EmbB protein has been proposed to be the target of ethambutol, a drug which is known to inhibit the synthesis of the arabinan portion of the mycobacterial cell wall arabinogalactan (AG). To further define the role of EmbB protein in arabinan biosynthesis, embA, -B, and -C genes were inactivated individually by homologous recombination in M. smegmatis. All three mutants were viable, and among the three, the slowest growing embB(-) mutant encountered profound morphological changes and exhibited a higher sensitivity to hydrophobic drugs and detergents, presumably due to an increase in cell wall permeability. Furthermore, chemical analyses showed that there was a diminution in the arabinose content of arabinogalactan from the embA(-) and embB(-) mutants. Specifically, in comparison with the wild-type strain, the crucial terminal hexaarabinofuranosyl motif, which is a template for mycolylation, was altered in both embA(-) and embB(-) mutants. Detailed nuclear magnetic resonance studies coupled with enzyme digestion, chromatography, and mass spectrometry analyses revealed that the disaccharide beta-d-Ara(f)-(1-->2)-alpha-d-Ara(f) extension from the 3-position of the 3,5-linked alpha-d-Ara(f) residue is markedly diminished. As a consequence, a linear terminal beta-d-Ara(f)-(1-->2)-alpha-d-Ara(f)-(1-->5)-alpha-d-Ara(f)-(1-->5)-alpha-d-Ara(f) is formed, a motif which is a recognized, nonreducing terminal feature of lipoarabinomannan but not of normal AG. Upon complementation with the embB and embA wild-type genes, the phenotype of the mutants reverted to wild-type, in that normal AG was resynthesized. Our results clearly show that both EmbA and EmbB proteins are involved in the formation of the proper terminal hexaarabinofuranoside motif in AG, thus paving the way for future studies to identify the complete array of arabinosyltransferases involved in the synthesis of mycobacterial cell wall arabinan.     

Development of a plate-based scintillation proximity assay for the mycobacterial AftB enzyme involved in cell wall arabinan biosynthesis

A number of mycobacterial arabinosyltransferases, such as the Emb proteins, AftA, AftB, AftC, and AftD have been characterized and implicated to be involved in the cell wall arabinan assembly. These arabinosyltransferases are essential for the viability of the organism and are logically valid targets for developing new anti-tuberculosis agents. For instance, Ethambutol, a first line anti-tuberculosis drug, targets the Emb proteins involved in the formation of the arabinan of cell wall arabinogalactan. Among these arabinosyltransferases, the terminal β-(1→2) arabinosyltransferase activity has been associated with AftB. The predicted topology of AftB in Mycobacterium tuberculosis has 10 N terminal transmembrane domains and a C terminal hydrophilic domain similar to the Emb proteins. It has a conserved GT-C motif and is difficult to express. In a cell free assay, synthetic disaccharide, α-d-Araf-(1→5)-α-d-Araf-octyl, has been used as a substrate to explore the function of AftB. In our work, the disaccharide was synthesized in its pentenylated and biotinylated form, and the enzymatic product formed was identified as the β-(1→2) arabinofuranose adduct. When synthetic tri- and tetra-saccharides were used as substrates, a mixture of products containing both β-(1→2) and α-(1→5) linkages were formed. Therefore, the biotinylated disaccharide was selected to develop a scintillation proximity assay.     

Development of a Quantitative Assay for Mycobacterial Endogenous Arabinase and Ensuing Studies of Arabinase Levels and Arabinan Metabolism in Mycobacterium smegmatis

Treatment of either Mycobacterium tuberculosis or M. smegmatis with ethambutol results both in inhibition of arabinan synthesis and in copious loss of previously formed arabinan from the cell wall. The loss of arabinan has been shown to be due to the action of an endogenous arabinase. To better understand this phenomenon, a quantitative assay for endogenous arabinase was developed. Using the assay it was determined that various subcellular fractions of M. smegmatis showed significant amounts of endogenous arabinase activity. Surprisingly, treatment with ethambutol yielded only minor changes in the amounts of endogenous arabinase activities. Endogenous arabinase was present in the cell wall, and consistently, incubation of the M. smegmatis cell wall in only buffer resulted in the release of arabinan, mimicking the effect of ethambutol on whole cells. To determine if cell wall arabinan is rapidly turned over, the arabinan was labeled in the early log phase of culture by feeding [¹⁴C]glucose, followed by a “chase” with nonradioactive glucose. Most of the labeled arabinan remained in the cell wall after the culture was grown to late log phase. Thus, there is active arabinase in the cell wall, but arabinan is not rapidly removed unless ethambutol is present. Purification of the endogenous arabinase, using the assay described, is ongoing to help further discern its biological function.     

Transfer of the first arabinofuranose residue to galactan is essential for Mycobacterium smegmatis viability

The mycobacterial arabinan is an elaborate component of the cell wall with multiple glycosyl linkages and no repeating units. In Mycobacterium spp., the Emb proteins (EmbA, EmbB, and EmbC) have been identified as putative mycobacterial arabinosyltransferases implicated in the biogenesis of the cell wall arabinan. Furthermore, it is now evident that the EmbA and EmbB proteins are involved in the assembly of the nonreducing terminal motif of arabinogalactan and EmbC is involved in transferring arabinose, perhaps in the early stage of arabinan synthesis in lipoarabinomannan. It has also been shown that the Emb proteins are a target of the antimycobacterial drug ethambutol (EMB). In the search for additional mycobacterial arabinosyltransferases in addition to the Emb proteins, we disrupted MSMEG_6386 (an orthologue of Rv3792 and a gene upstream of embC) in Mycobacterium smegmatis. Allelic exchange at the chromosomal MSMEG_6386 locus of M. smegmatis could only be achieved in the presence of a rescue plasmid carrying a functional copy of MSMEG_6386 or Rv3792, strongly suggesting that MSMEG_6386 is essential. An in vitro arabinosyltransferase assay using a membrane preparation from M. smegmatis expressing Rv3792 and synthetic beta-d-Galf-(1-->5)-beta-D-Galf-(1-->6)-beta-D-Galf-octyl and beta-D-Galf-(1-->6)-beta-D-Galf-(1-->5)-beta-D-Galf-octyl showed that Rv3792 gene product can transfer an arabinose residue to the C-5 position of the internal 6-linked galactose. The reactions were insensitive to EMB, and when alpha-d-Manp-(1-->6)-alpha-D-Manp-(1-->6)-alpha-D-Manp-octylthiomethyl was used as an acceptor, no product was formed. These observations indicate that transfer of the first arabinofuranose residue to galactan is essential for M. smegmatis viability.     

Fluorescent phospholipid analogs as microscopic probes for detection of the mycolic acid-containing layer in Corynebacterium glutamicum: detecting alterations in the mycolic acid-containing layer following ethambutol treatment

Corynebacterium glutamicum belongs to the mycolic acid-containing actinomycetes, which also include Mycobacterium, Nocardia, and Rhodococcus. The cells of this group possess a cell wall with a thick outer layer composed primarily of mycolic acid, which functions as a permeability barrier. To investigate the mechanism of mycolic acid-containing layer (mycolate layer) formation, we have developed a fluorescence microscopic technique detecting the mycolate layer in situ. The staining specificity of fluorescence-labeled phospholipid analogs was determined by simultaneous staining with the hydrophobic fluorescent dye Nile Red and peptidoglycan-staining fluorescence-conjugated vancomycin. We found that fluorescence-labeled phospholipid analogs preferentially stain the mycolate layer. Using this technique, we observed the effect of the anti-mycobacterial drug ethambutol on C. glutamicum mycolate-layer formation. Ethambutol interfered specifically with mycolate-layer formation on the division planes and cell poles, while the side-wall mycolate layer was not severely affected. This indicates that mycolate-layer formation occurs mainly on division planes and cell poles in C. glutamicum, where the peptidoglycan layer is actively synthesized.     

Identification of an anion-specific channel in the cell wall of the Gram-positive bacterium Corynebacterium glutamicum

A cation-selective channel (porin), designated PorA, facilitates the passage of hydrophilic solutes across the cell wall of the mycolic acid-containing actinomycete Corynebacterium glutamicum. Biochemical and electrophysiological investigations of the cell wall of the mutant strain revealed the presence of an alternative channel-forming protein. This porin was purified to homogeneity and studied in lipid bilayer membranes. It forms small anion-selective channels with a diameter of about 1.4 nm and an average single-channel conductance of about 700 pS in 1 M KCl. The PorBCglut channel could be blocked by citrate in a dose-dependent manner. This result was in agreement with growth experiments in citrate as sole carbon source where growth in citrate was impaired as compared with growth in other carbon sources. The PorBCglut protein was partially sequenced and based on the resulting amino acid sequence of the corresponding gene, which was designated as porB, was identified as an unannotated 381 bp long open reading frame (ORF) in the published genome sequence of C. glutamicum ATCC13032. PorBCglut contains 126 amino acids with an N-terminal extension of 27 amino acids. One hundred and thirty-eight base pairs downstream of porB, we found an ORF that codes for a protein with about 30% identity to PorBCglut, which was named PorCCglut. The arrangement of porB and porC on the chromosome suggested that both genes belong to the same cluster. RT-PCR from overlapping regions between genes from wild-type C. glutamicum ATCC 13032 and its ATCC 13032DeltaporA mutant demonstrated that this is the case and that porB and porC are cotranscribed. The gene products PorBCglut and PorCCglut represent obviously other permeability pathways for the transport of hydrophilic compounds through the cell wall of C. glutamicum.     

Exposure of mycobacteria to cell wall-inhibitory drugs decreases production of arabinoglycerolipid related to Mycolyl-arabinogalactan-peptidoglycan metabolism

The "cell wall core" consisting of a mycolyl-arabinogalactan-peptidoglycan (mAGP) complex represents the hallmark of the mycobacterial cell envelope. It has been the focus of intense research at both structural and biosynthetic levels during the past few decades. Because it is essential, mAGP is also regarded as a target for several antitubercular drugs. Herein, we demonstrate that exposure of Mycobacterium bovis Bacille Calmette-Guérin or Mycobacterium marinum to thiacetazone, a second line antitubercular drug, is associated with a severe decrease in the level of a major apolar glycolipid. This inhibition requires MmaA4, a methyltransferase reported to participate in the activation process of thiacetazone. Following purification, this glycolipid was subjected to detailed structural analyses, combining gas-liquid chromatography, mass spectrometry, and nuclear magnetic resonance. This allowed to identify it as a 5-O-mycolyl-β-Araf-(1→2)-5-O-mycolyl-α-Araf-(1→1)-Gro, designated dimycolyl diarabinoglycerol (DMAG). The presence of DMAG was subsequently confirmed in other slow growing pathogenic species, including Mycobacterium tuberculosis. DMAG production was stimulated in the presence of exogenous glycerol. Interestingly, DMAG appears structurally identical to the terminal portion of the mycolylated arabinosyl motif of mAGP, and the metabolic relationship between these two components was provided using antitubercular drugs such as ethambutol or isoniazid known to inhibit the biosynthesis of arabinogalactan or mycolic acid, respectively. Finally, DMAG was identified in the cell wall of M. tuberculosis. This opens the possibility of a potent biological function for DMAG that may be important to mycobacterial pathogenesis.