Identification of a mycoloyl transferase selectively involved in O-acylation of polypeptides in Corynebacteriales.

We have previously described the posttranslational modification of pore-forming small proteins of Corynebacterium by mycolic acid, a very-long-chain α-alkyl and ß-hydroxy fatty acid. Using a combination of chemical analyses and mass spectrometry, we identified the mycoloyl transferase (Myt) that catalyzes the transfer of the fatty acid residue to yield O-acylated polypeptides. Inactivation of corynomycoloyl transferase C (cg0413 [Corynebacterium glutamicum mytC {CgmytC}]), one of the six Cgmyt genes of C. glutamicum, specifically abolished the O-modification of the pore-forming proteins PorA and PorH, which is critical for their biological activity. Expectedly, complementation of the cg0413 mutant with either the wild-type gene or its orthologues from Corynebacterium diphtheriae and Rhodococcus, but not Nocardia, fully restored the O-acylation of the porins. Consistently, the three-dimensional structure of CgMytC showed the presence of a unique loop that is absent from enzymes that transfer mycoloyl residues onto both trehalose and the cell wall arabinogalactan. These data suggest the implication of this structure in the enzyme specificity for protein instead of carbohydrate.

Structural elucidation and genomic scrutiny of the C60-C100 mycolic acids of Segniliparus rotundus.

Mycolic acids, very long-chain α-alkyl, ß-hydroxylated fatty acids, occur in the members of the order Corynebacteriales where their chain lengths (C(26)-C(88)) and structural features (oxygen functions, cis or trans double bonds, cyclopropane rings and methyl branches) are genus- and species-specific. The molecular composition and structures of the mycolic acids of two species belonging to the genus Segniliparus were determined by a combination of modern analytical chemical techniques, which include MS and NMR. They consist of mono-ethylenic C(62-)C(64) (α'), di-ethylenic C(77)-C(79) (α) and extremely long-chain mycolic acids (α(+)) ranging from 92 to 98 carbon atoms and containing three unsaturations, cis and/or trans double bonds and/or cyclopropanes. The double bonds in each class of mycolic acids were positioned by oxidative cleavage and exhibit locations similar to those of α- and α'-mycolic acids of mycobacteria. For the ultralong chain α-mycolic acids, the three double bonds were located at equally spaced carbon intervals (C(13)-C(16)), with the methyl branches adjacent to the proximal and distal trans double bonds. Examination of the Segniliparus rotundus genome compared with those of other members of the Corynebacteriales indicated two obvious differences in genes encoding the elongation fatty acid (FAS-II) enzymes involved in the biosynthesis of mycolic acids: the organization of 3-ketoacyl-ACP synthases (KasA and KasB) and (3R)-hydroxyacyl-ACP dehydratases (HadAB/BC), on one hand, and the presence of two copies of the hadB gene encoding the catalytic domain of the latter enzyme type, on the other. This observation is discussed in light of the most recent data accumulated on the biosynthesis of this hallmark of Corynebacteriales.

Biochemical disclosure of the mycolate outer membrane of Corynebacterium glutamicum.

Corynebacterineae is a specific suborder of Gram-positive bacteria that includes Mycobacterium tuberculosis and Corynebacterium glutamicum. The cell wall of these bacteria is composed of a heteropolymer of peptidoglycan (PG) linked to arabinogalactan (AG), which in turn is covalently associated with an atypical outer membrane, here called mycomembrane (M). The latter structure has been visualized by cryo-electron microscopy of vitreous sections, but its biochemical composition is still poorly defined, thereby hampering the elucidation of its physiological function. In this report, we show for the first time that the mycomembrane-linked heteropolymer of PG and AG (M-AG-PG) of C. glutamicum can be physically separated from the inner membrane on a flotation density gradient. Analysis of purified M-AG-PG showed that the lipids that composed the mycomembrane consisted almost exclusively of mycolic acid derivatives, with only a tiny amount, if any, of phospholipids and lipomannans, which were found with the characteristic lipoarabinomannans in the plasma membrane. Proteins associated with or inserted in the mycomembrane were extracted from M-AG-PG with lauryl-dimethylamine-oxide (LDAO), loaded on an SDS-PAGE gel, and analyzed by tandem mass spectrometry or by Western blotting. Sixty-eight different proteins were identified, 19 of which were also found in mycomembrane fragments released by the terminal-arabinosyl-transferase-defective ΔAftB strain. Almost all of them are predicted to contain a signal sequence and to adopt the characteristic ß-barrel structure of Gram-negative outer membrane proteins. These presumed mycomembrane proteins include the already-known pore-forming proteins (PorA and PorB), 5 mycoloyltransferases (cMytA, cMytB, cMytC, cMytD, and cMytF), several lipoproteins, and unknown proteins typified by a putative C-terminal hydrophobic anchor.

Structural reorganization of the antigen-binding groove of human CD1b for presentation of mycobacterial sulfoglycolipids.

The mechanisms permitting nonpolymorphic CD1 molecules to present lipid antigens that differ considerably in polar head and aliphatic tails remain elusive. It is also unclear why hydrophobic motifs in the aliphatic tails of some antigens, which presumably embed inside CD1 pockets, contribute to determinants for T-cell recognition. The 1.9-Å crystal structure of an active complex of CD1b and a mycobacterial diacylsulfoglycolipid presented here provides some clues. Upon antigen binding, endogenous spacers of CD1b, which consist of a mixture of diradylglycerols, moved considerably within the lipid-binding groove. Spacer displacement was accompanied by F' pocket closure and an extensive rearrangement of residues exposed to T-cell receptors. Such structural reorganization resulted in reduction of the A' pocket capacity and led to incomplete embedding of the methyl-ramified portion of the phthioceranoyl chain of the antigen, explaining why such hydrophobic motifs are critical for T-cell receptor recognition. Mutagenesis experiments supported the functional importance of the observed structural alterations for T-cell stimulation. Overall, our data delineate a complex molecular mechanism combining spacer repositioning and ligand-induced conformational changes that, together with pocket intricacy, endows CD1b with the required molecular plasticity to present a broad range of structurally diverse antigens.

O-mycoloylated proteins from Corynebacterium: an unprecedented post-translational modification in bacteria.

O-acylation of proteins was known only in a few eukaryotic proteins but never in bacteria. We demonstrate, using a combination of protein chemistry and mass spectrometry, the occurrence of three O-acylated polypeptides in Corynebacterium glutamicum, PorA, PorH, and an unknown small protein. The three polypeptides are O-substituted by mycolic acids, long chain alpha-alkyl and beta-hydroxy fatty acids specifically produced by members of the Corynebacterineae suborder. To date these acids were described only as esterifying trehalose and arabinogalactan, and less frequently glycerol, important components of the highly impermeable outer barrier of Corynebacterineae. We show that the post-translational mycoloylation of PorA occurs at Ser-15 and is necessary for the pore-forming activity of C. glutamicum.

Identification of a stress-induced factor of Corynebacterineae that is involved in the regulation of the outer membrane lipid composition.

Corynebacterineae are gram-positive bacteria that possess a true outer membrane composed of mycolic acids and other lipids. Little is known concerning the modulation of mycolic acid composition and content in response to changes in the bacterial environment, especially temperature variations. To address this question, we investigated the function of the Rv3802c gene, a gene conserved in Corynebacterineae and located within a gene cluster involved in mycolic acid biosynthesis. We showed that the Rv3802 ortholog is essential in Mycobacterium smegmatis, while its Corynebacterium glutamicum ortholog, NCgl2775, is not. We provided evidence that the NCgl2775 gene is transcriptionally induced under heat stress conditions, and while the corresponding protein has no detectable activity under normal growth conditions, the increase in its expression triggers an increase in mycolic acid biosynthesis concomitant with a decrease in phospholipid content. We demonstrated that these lipid modifications are part of a larger outer membrane remodeling that occurs in response to exposure to a moderately elevated temperature (42 degrees C). In addition to showing an increase in the ratio of saturated corynomycolates to unsaturated corynomycolates, our results strongly suggested that the balance between mycolic acids and phospholipids is modified inside the outer membrane following a heat challenge. Furthermore, we showed that these lipid modifications help the bacteria to protect against heat damage. The NCgl2775 protein and its orthologs thus appear to be a protein family that plays a role in the regulation of the outer membrane lipid composition of Corynebacterineae under stress conditions. We therefore propose to name this protein family the envelope lipids regulation factor (ElrF) family.

Partial redundancy in the synthesis of the D-arabinose incorporated in the cell wall arabinan of Corynebacterineae.

The major cell wall carbohydrate of Corynebacterineae is arabinogalactan (AG), a branched polysaccharide that is essential for the physiology of these bacteria. Decaprenylphosphoryl-D-arabinose (DPA), the lipid donor of D-arabinofuranosyl residues of AG, is synthesized through a series of unique biosynthetic steps, the last one being the epimerization of decaprenylphosphoryl-beta-D-ribose (DPR) into DPA, which is believed to proceed via a sequential oxidation-reduction mechanism. Two proteins from Mycobacterium tuberculosis (Rv3790 and Rv3791) have been shown to catalyse this epimerization in an in vitro system. The present study addressed the exact function of these proteins through the inactivation of the corresponding orthologues in Corynebacterium glutamicum (NCgl0187 and NCgl0186, respectively) and the analysis of their in vivo effects on AG biosynthesis. We showed that NCgl0187 is essential, whereas NCgl0186 is not. Deletion of NCgl0186 led to a mutant possessing an AG that contained half the arabinose and rhamnose, and less corynomycolates linked to AG but more trehalose mycolates, compared with the parental strain. A candidate gene that may encode a protein functionally similar to NCgl0186 was identified in both C. glutamicum (NCgl1429) and M. tuberculosis (Rv2073c). While the deletion of NCgl1429 had no effect on AG biosynthesis of the mutant, the gene could complement the mycolate defect of the AG of the NCgl0186 mutant, strongly supporting the concept that the two proteins play a similar function in vivo. Consistent with this, the NCgl1429 gene appeared to be essential in the NCgl0186-inactivated mutant. A detailed bioinformatics analysis showed that NCgl1429, NCgl0186, Rv3791 and Rv2073c could constitute, with 52 other proteins belonging to the actinomycetales, a group of closely related short-chain reductases/dehydrogenases (SDRs) with atypical motifs. We propose that the epimerization of DPR to DPA involves three enzymes that catalyse two distinct steps, each being essential for the viability of the bacterial cells.