The mycobacterial bacillus is encompassed by a remarkably elaborate cell wall structure. The mycolyl-arabinogalactan-peptidoglycan (mAGP) complex is essential for the viability of Mycobacterium tuberculosis and maintains a robust basal structure supporting the upper "myco-membrane." M. tuberculosis peptidoglycan, although appearing to be unexceptional at first glance, contains a number of unique molecular subtleties that become particularly important as the TB-bacilli enters into nonreplicative growth during dormancy. Arabinogalactan, a highly branched polysaccharide, serves to connect peptidoglycan with the outer mycolic acid layer, and a variety of unique glycolsyltransferases are used for its assembly. In this review, we shall explore the microbial chemistry of this unique heteropolysacchride, examine the molecular genetics that underpins its fabrication, and discuss how the essential biosynthetic process might be exploited for the development of future anti-TB chemotherapies. THE MYCOBACTERIAL CELL WALL-PEPTIDOGLYCAN AND ARABINOGALACTAN
Many transcription factors, including the Escherichia coli cyclic AMP receptor protein (CRP), act by making direct contacts with RNA polymerase. At Class II CRP-dependent promoters, CRP activates transcription by making two such contacts: (i) an interaction with the RNA polymerase alpha subunit C-terminal domain (alphaCTD) that facilitates initial binding of RNA polymerase to promoter DNA; and (ii) an interaction with the RNA polymerase alpha subunit N-terminal domain that facilitates subsequent promoter opening. We have used random mutagenesis and alanine scanning to identify determinants within alphaCTD for transcription activation at a Class II CRP-dependent promoter. Our results indicate that Class II CRP-dependent transcription requires the side chains of residues 265, 271, 285-288 and 317. Residues 285-288 and 317 comprise a discrete 20x10 A surface on alphaCTD, and substitutions within this determinant reduce or eliminate cooperative interactions between alpha subunits and CRP, but do not affect DNA binding by alpha subunits. We propose that, in the ternary complex of RNA polymerase, CRP and a Class II CRP-dependent promoter, this determinant in alphaCTD interacts directly with CRP, and is distinct from and on the opposite face to the proposed determinant for alphaCTD-CRP interaction in Class I CRP-dependent transcription.
Alanine scanning of the Escherichia coli RNA polymerase ␣ subunit C-terminal domain (␣CTD) was used to identify amino acid side chains important for class I cyclic AMP receptor protein (CRP)-dependent transcription. Key residues were investigated further in vivo and in vitro. Substitutions in three regions of ␣CTD affected class I CRP-dependent transcription from the CC(؊61.5) promoter and/or the lacP1 promoter. These regions are (i) the 287 determinant, previously shown to contact CRP during class II CRP-dependent transcription; (ii) the 265 determinant, previously shown to be important for ␣CTD-DNA interactions, including those required for class II CRP-dependent transcription; and (iii) the 261 determinant. We conclude that CRP contacts the same target in ␣CTD, the 287 determinant, at class I and class II CRP-dependent promoters. We also conclude that the relative contributions of individual residues within the 265 determinant depend on promoter sequence, and we discuss explanations for effects of substitutions in the 261 determinant.The ␣ subunits of Escherichia coli RNA polymerase holoenzyme (RNAP) play a key role in transcription initiation and activation (reviewed in references 5 and 11). Each ␣ subunit consists of two independently folded domains connected by a flexible linker (4,12,13). The N-terminal domain (␣NTD) is critical for the assembly of the core RNAP complex (5). The C-terminal domain (␣CTD) binds to A/T-rich sequence elements (UP elements) at many promoters (11,22) and is also a target for transcription activators, with many activators interacting directly with ␣CTD and recruiting it, and consequently the rest of RNAP, to target promoter DNA (5). The structure of ␣CTD has been determined by nuclear magnetic resonance spectroscopy (8,12). The aim of this study was to identify the contact target in ␣CTD for the transcription activator cyclic AMP (cAMP) receptor protein (CRP; also referred to as catabolite activator protein).Transcription activation by CRP provides an important model system for understanding mechanisms of bacterial transcriptional regulation (reviewed in reference 6). CRP is a homodimer that binds to DNA in the presence of cAMP. Simple CRP-dependent promoters can be grouped into two classes, depending on the location of the DNA binding site for CRP. At class I CRP-dependent promoters, CRP binds upstream of RNAP, at sites centered near position Ϫ61, Ϫ71, Ϫ82, or Ϫ92 upstream from the transcription start site. The best-characterized class I CRP-dependent promoters are lacP1 and a semisynthetic derivative of the melR promoter, CC(Ϫ61.5) (9), each of which contains a CRP-binding site centered at position Ϫ61.5. At class II CRP-dependent promoters, the CRP-binding site overlaps the binding site for RNAP. The best-characterized class II CRP-dependent promoters are galP1 and a semisynthetic derivative of the melR promoter, CC(Ϫ41.5) (9), each of which contains a CRP-binding site centered at position Ϫ41.5.At both class I and class II CRP-dependent promoters, CRP interacts with ␣CTD, fa...
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.
The d-arabinan-containing polymers arabinogalactan (AG) and lipoarabinomannan (LAM) are essential components of the unique cell envelope of the pathogen Mycobacterium tuberculosis. Biosynthesis of AG and LAM involves a series of membrane-embedded arabinofuranosyl (Araf) transferases whose structures are largely uncharacterised, despite the fact that several of them are pharmacological targets of ethambutol, a frontline drug in tuberculosis therapy. Herein, we present the crystal structure of the C-terminal hydrophilic domain of the ethambutol-sensitive Araf transferase M. tuberculosis EmbC, which is essential for LAM synthesis. The structure of the C-terminal domain of EmbC (EmbCCT) encompasses two sub-domains of different folds, of which subdomain II shows distinct similarity to lectin-like carbohydrate-binding modules (CBM). Co-crystallisation with a cell wall-derived di-arabinoside acceptor analogue and structural comparison with ligand-bound CBMs suggest that EmbCCT contains two separate carbohydrate binding sites, associated with subdomains I and II, respectively. Single-residue substitution of conserved tryptophan residues (Trp868, Trp985) at these respective sites inhibited EmbC-catalysed extension of LAM. The same substitutions differentially abrogated binding of di- and penta-arabinofuranoside acceptor analogues to EmbCCT, linking the loss of activity to compromised acceptor substrate binding, indicating the presence of two separate carbohydrate binding sites, and demonstrating that subdomain II indeed functions as a carbohydrate-binding module. This work provides the first step towards unravelling the structure and function of a GT-C-type glycosyltransferase that is essential in M. tuberculosis.
Recent genomic studies with Escherichia coli K-12 have suggested scores of previously unexplored targets for the cyclic AMP receptor protein (CRP) global transcription regulator. Eleven of these loci were cloned and CRP binding was demonstrated at eight of these targets. It is shown that CRP can activate transcription at five of these targets and the functional DNA sites for CRP are identified. It is reported that CRP functions as a Class I activator at the aer promoter and as a Class II activator at the gatY, sdaC, ychH and malX promoters.
Mycobacterium tuberculosis, the etiological agent of tuberculosis (TB), has a unique cell envelope which accounts for its unusual low permeability and contributes to resistance against common antibiotics. The main structural elements of the cell wall consist of a cross-linked network of peptidoglycan (PG) in which some of the muramic acid residues are covalently attached to a complex polysaccharide, arabinogalactan (AG), via a unique α-l-rhamnopyranose–(1→3)-α-d-GlcNAc-(1→P) linker unit. While the molecular genetics associated with PG and AG biosynthetic pathways have been largely delineated, the mechanism by which these two major pathways converge has remained elusive. In Gram-positive organisms, the LytR-CpsA-Psr (LCP) family of proteins are responsible for ligating cell wall teichoic acids to peptidoglycan, through a linker unit that bears a striking resemblance to that found in mycobacterial arabinogalactan. In this study, we have identified Rv3267 as a mycobacterial LCP homolog gene that encodes a phosphotransferase which we have named Lcp1. We demonstrate that lcp1 is an essential gene required for cell viability and show that recombinant Lcp1 is capable of ligating AG to PG in a cell-free radiolabeling assay.
Transcription initiation is the principal step at which bacterial gene expression is regulated. Bacterial transcription is due to a single multisubunit RNA polymerase. The potential transcription initiation rate of any promoter is set by the efficiency with which RNA polymerase recognizes the different promoter sequence elements. The sigma subunit plays the major role in the process of promoter recognition. Different RNA polymerase sigma subunits can guide RNA polymerase to different promoters. The E. coli genome encodes seven different sigma subunits, each of which allows the cell to respond to different environmental stimuli. A large number of transcription factors up-regulate and down-regulate expression from different promoters in response to environmental signals. Many transcription activators function by making a direct interaction with RNA polymerase. Some activators function by altering the conformation of promoter DNA. Most transcription repressors function by blocking access of RNA polymerase to their target promoter. In some cases, optimal repression depends on multiply bound repressor molecules that interact in complex ways. Many promoters are regulated by more than one transcription factor. A variety of mechanisms whereby a promoter can be regulated by a repressor and an activator, or by two activators, is known.
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