Introduction
The covalent modification of bacterial (lipo)polysaccharides with various (amino)sugars, amino acids, phosphates or acyl groups has been reported to control their biosynthesis and export in addition to impacting the interactions of bacteria with the host and their resistance to antimicrobials [1–7]. While devoid of the canonical lipopolysaccharides (LPS) and (lipo)teichoic acids found in other prokaryotes, mycobacteria produce two distinct heteropolysaccharides, arabinogalactan (AG) and lipoarabinomannan (LAM). Both polymers are critical to the integrity of the cells and are known to be modified by discrete covalent modifications [8]. The biological significance of these modifications remains largely unknown.
LAM has three distinct structural domains including a phosphatidylinositol anchor, a mannan core which consists of α(1→6)-linked mannosyl residues substituted at some positions with single mannoses or mannan side chains, and an arabinan consisting of α(1→5)-linked arabinosyl residues with some α(1→3)-branching [Fig 1]. Three distinct motifs, known as Ara4, Ara5 and Ara6, make up the non-reducing arabinan termini of LAM, all ending in β(1→2)-linked arabinosyl units [9,10] [Fig 1]. M. tuberculosis (Mtb) AG is made of a galactan domain and one or two arabinan chains that are very similar in structure to that of LAM except for the fact its non-reducing arabinan termini exclusively consist of Ara6 motifs [11,12] [Fig 1]. Decorating these relatively conserved LAM and AG core structures are a number of discrete, precisely positioned, covalent substituents. The non-reducing arabinan termini of LAM, in particular, display considerable species-specific structural heterogeneity which is known to be key to the biological activity of the entire molecule. One of the best characterized arabinan termini substituents are mannoside caps found on the LAM of Mtb and a number of other pathogenic slow-growing mycobacteria. These substituents have been associated with numerous biological activities aimed at promoting intracellular survival and immune evasion. Studies conducted for the most part using purified LAM have indeed implicated the mannoside caps of LAM in the ability of the lipoglycan to bind to C-type lectins (mannose receptor, dectin-2 and DC-SIGN), inhibit phagosomal maturation and Mtb-induced apoptosis and autophagy, impair signaling pathways of phagocytic cells and T-lymphocytes, and stimulate an anti-inflammatory response [9,13–16]. The role of other covalent modifications of LAM and AG in mycobacterial physiology and infection is less well defined [8].
[Figure omitted. See PDF.]
Fig 1. Detail of the covalent substituents modifying the arabinan domains of AG and LAM in Mtb.
The various chemical modifications found on AG, LM, and LAM are shown in colored boxes: Mannoside caps: yellow boxes; succinyl substituents: green; methylthioxylose (MTX): orange, galactosamine: gray. The succinylation of the mycolylated chains in AG has been reported to be diminished or absent compared to that of non-mycolylated chains [22]. Ara5 motifs, not shown on this figure, are thought to be extended linear Ara4 motifs harboring one additional Araf residue [10].
https://doi.org/10.1371/journal.ppat.1011636.g001
We and others reported on the presence of succinyl substituents on the arabinan domains of AG and LAM of Mtb, M. smegmatis, M. abscessus and M. bovis BCG, and on the identity of the succinyltransferase (named SucT) responsible for their addition to both polysaccharides [17–19] [Fig 1]. An interesting feature shared by sucT-deficient mutants in all Mycobacterium spp. analyzed to date relates to their altered cell surface properties as evidenced by changes in their colony morphology, biofilm forming capacity, surface hydrophobicity and/or aggregative properties [17–18,20–21]. On the basis of these observations, we proposed that the succinylation of the two major polysaccharides of the mycobacterial cell envelope served to modulate, probably through indirect charge-mediated effects, the surface properties of bacilli thereby allowing the bacterium to adjust the way it interacts with its environment [18]. The fact that the prevalence of succinyl substituents on Mtb LAM increases during murine infection supports a role in host adaptation [10]. That succinylation may also control the elongation, branching and other modifications of LAM and AG has been proposed but never conclusively answered [22]. Structural analyses of the AG and LAM produced by sucT mutants of the fast-growing M. smegmatis and M. abscessus revealed that they display wild-type structures [17–18]. In contrast, and although not known to be impacted in the succinylation of AG and LAM at the time, a sucT mutant of the slow-growing Mycobacterium species, M. marinum, was reported to produce a LAM devoid of mannoside caps, with a higher degree of branching of both its mannan and arabinan domains, and a reduced acylation of its phosphatidylinositol anchor [20].
To further explore the physiological implications of LAM and AG succinylation in mycobacteria and address potential differences between slow- and fast-growing species, we here studied the impact of disrupting sucT on the biosynthesis of AG and LAM in the major human pathogen, Mtb, and interactions of this bacterium with innate immune cells.
Results
Impact of sucT disruption on the structure of Mtb LAM
A Mtb CDC1551 mutant, Mtb sucT::Tn, harboring a transposon insertion at position 614 of the MT1616 gene was obtained from BEI Resources [23]. MT1616 is 100, 75, 61 and 83% identical at the amino acid level with SucT from Mtb H37Rv (Rv1565c), M. smegmatis, M. abscessus, and M. marinum, respectively. Complemented mutant strains were generated by transforming Mtb sucT::Tn with either the replicative plasmid pMVGH1-Rv1565c harboring a wild-type (WT) copy of the Mtb sucT gene under control of the hsp60 promoter (Mtb sucT::Tn comp) or the integrative plasmid pMV306H harboring a WT copy of Mtb sucT similarly expressed under control of the hsp60 promoter (Mtb sucT::Tn comp-int).
Analysis of the lipoglycans from the WT, mutant and complemented mutant strains by SDS-PAGE pointed to the slightly faster migration of the LAM from Mtb sucT::Tn relative to the WT and complemented mutant LAM [Fig 2A], which was opposite to what had been reported for the LAM produced by sucT mutants of M. smegmatis and M. abscessus [17–18] and was suggestive of a smaller size LAM in the case of Mtb sucT::Tn.
[Figure omitted. See PDF.]
Fig 2. Biochemical analysis of LAM and AG prepared from WT Mtb CDC1551, the sucT mutant and the complemented sucT mutant strains.
(A) Electrophoretic mobility of LM and LAM. Lipoglycans purified from WT Mtb CDC1551, Mtb sucT::Tn, and Mtb sucT::Tn/pMVGH1-Rv1565c (Mtb sucT::Tn comp) were run on a 10–20% Tricine gel followed by periodic acid-silver staining. The results presented are representative of two independent SDS-PAGE runs using different lipoglycan preparations from each strain. (B) Succinate content of AG and LAM. GC/MS-based quantification of succinates and arabinose residues in the same LAM and mAGP samples prepared from the WT, mutant and complemented mutant strains. An assumption is made here based on other structural analyses (alditol acetate and glycosyl linkage analyses presented in S1 through S4 Tables) that the arabinan domains of LAM and AG are not significantly altered in the mutant. Results are expressed as average ± SD succinate/arabinose molar ratios from three technical replicates. Asterisks denote statistical differences (*p < 0.05; **p < 0.005; ***p < 0.0005, Student’s t-test). The two complemented mutant strains shown here are: Mtb sucT::Tn/pMVGH1-Rv1565c (sucT expressed under control of the hsp60 promoter from a replicative plasmid; Mtb sucT::Tn comp) and Mtb sucT::Tn/pNIP40b-Rv1565c (sucT expressed under control of the hsp60 promoter from an integrative plasmid; Mtb sucT::Tn comp-int). (C) NMR analysis of LAM. Shown are the 1D 1H (i, iii and v) and 2D 1H-13C (ii, iv and vi) HMQC NMR spectra of LAM purified from Mtb CDC1551 WT, Mtb sucT::Tn and Mtb sucT::Tn comp. Arrows point to the signals typifying succinates. The 1D 1H spectra of the WT and complemented mutant LAM show the characteristic two pseudo-triplets (J = 6.5 Hz) of similar intensity at 2.50 and 2.65 ppm assigned to methylene groups of succinyl units (panels i and v). Their corresponding carbons were characterized at 34.7 and 33.3 ppm, respectively, on the 2D 1H-13C HMQC spectra (panels ii and vi). These signals are absent from the sucT mutant 1D 1H and 2D 1H-13C HMQC NMR spectra (panels iii and iv). (D) Quantification of mannooligosaccharide caps in the LAM from WT Mtb, the sucT mutant and the complemented mutant strain, Mtb sucT::Tn comp. Left panel: Capillary electrophoresis cap profile of LAM prepared from the three strains. Right panel: Abundance of the different cap motifs per LAM molecule. White bars, WT Mtb CDC1551; black bars, Mtb sucT::Tn; grey bars, Mtb sucT::Tn comp. IS, internal standard, mannoheptose-APTS; AM, Manp-(α1→5)-Ara-APTS (mono-mannoside cap); AMM, Manp-(α1→2)-Manp-(α1→5)-Ara-APTS (di-mannoside cap); AMMM, Manp-(α1→2)-Manp-(α1→2)-Manp-(α1→5)-Ara-APTS (tri-mannoside cap). The results are shown are averages and standard deviations from three technical replicates. Asterisks denote statistical differences pursuant to the Student’s t-test (***p<0.0001; **p<0.005; *p<0.05. ns = not significant).
https://doi.org/10.1371/journal.ppat.1011636.g002
The degree of succinylation of Mtb sucT::Tn LAM relative to that produced by the WT and complemented mutant strains was first quantified by gas chromatography-mass spectrometry (GC/MS) analysis of succinates (as their dibutyl ester derivatives) obtained from purified LAM from each strain [17]. The results showed an almost complete absence of succinates in the mutant LAM [Fig 2B]. This result was confirmed by liquid chromatography-mass spectrometry (LC/MS) analysis of the oligoarabinosides released by the WT, mutant and complemented mutant LAM upon digestion with the Cellulomonas gelida endoarabinanase [Table 1 and S1 Fig], and 1D 1H and 2D 1H-13C HMQC NMR analyses of the LAM from the same strains [Fig 2C].
[Figure omitted. See PDF.]
Table 1. LC/MS analysis of the unmodified and covalently modified oligoarabinosides released from the LAM of Mtb CDC1551 WT, the sucT mutant and the complemented sucT mutant upon Cellulomonas gelida endoarabinanase digestion.
Shown in bold letters are the relative percentages of total (including, unmodified and covalently modified) Ara4, Ara5 and Ara6 oligoarabinosides released upon Cellulomonas gelida endoarabinanase digestion of LAM from the different strains and the individual representation (expressed as percentages) of unmodified and covalently modified oligoarabinosides within each group. Suc, succinate; MTX, methylthioxylose; Manx, mannoside cap containing x mannose residues. This experiment was performed once on the same LAM preparations from the WT, mutant (“sucT”) and complemented mutant (“sucT comp”) as used in the GC/MS, NMR and capillary electrophoresis analyses shown in Fig 2.
https://doi.org/10.1371/journal.ppat.1011636.t001
Another striking observation that arose from the LC/MS analysis of the oligoarabinosides released by the different LAMs upon digestion with the endoarabinanase was the dramatically reduced presence of mannoside caps (and thus, concomitantly, methylthio-D-xylose [MTX] motif) on the non-reducing arabinan termini of the mutant LAM (98.4, 79.4 and 97% reduction on the Ara4, Ara5 and Ara6 termini, respectively, compared to the WT strain) [Figs 1 and S1 and Table 1]. This result was confirmed by mild acid hydrolysis of purified LAM followed by analysis of liberated oligosaccharides by capillary electrophoresis which revealed a 96.7% decrease in the amount of combined mono-, di-, and tri-mannoside caps per molecule of LAM in the sucT mutant relative to the WT strain [Fig 2D]. Mannoside capping was restored in the complemented mutant [Table 1 and Figs 2D and S1]. The absence of mannoside caps on the mutant LAM likely explains its faster migration on SDS-PAGE since purified LAM from mutants deficient in the expression of the mannosyltransferase required for the addition of the first Manp residue of the caps, CapA, was reported earlier to display a similar migration pattern [24–26].
Quantitative analyses of the alditol acetate and per-O-methylated alditol acetate derivatives of the WT, mutant and complemented mutant LM revealed near identical structures in all three strains [S1 and S2 Tables]. Parallel analyses conducted on their LAM, in contrast, showed an increase in the Araf to Manp ratio of the mutant LAM that accompanied an increase in terminal Araf and a decrease in terminal Manp and 2-linked Manp residues, consistent with the loss of mannoside caps [S1 and S2 Tables]. The relative proportion of Ara4, Ara5 and Ara6 arabinan termini of LAM was otherwise comparable in all three strains as was the relative abundance of β-2-linked Araf residues which serve as acceptors for the mannoside caps of LAM [Tables 1 and S2]. The fatty acyl composition of the LM and LAM lipid anchors of all three strains was also comparable, except for a slight increase in the tuberculostearic acid content of LM in the mutant and complemented mutant strains at the expense of oleic acid [S3 Table].
Since a sucT mutant of M. marinum was reported earlier to display a reduction in the acylation of polar forms of phosphatidylinositol mannosides (PIM) [20], which are metabolic precursors of LM and LAM, we further analyzed the PIM composition of the WT, mutant and complemented strains by thin-layer chromatography and LC/MS, but did not observe any decrease in the phosphatidylinositol hexamannoside content of the mutant relative to the other two strains or changes in the acylation pattern of these glycolipids [S2 Fig].
In conclusion, the inactivation of sucT in Mtb led to the abolition of succinylation and almost complete loss of mannoside caps and MTX motifs on LAM. Loss of mannoside capping was the only phenotype shared by the Mtb and M. marinum sucT mutants since Mtb sucT::Tn produced otherwise a WT-like LAM with regard to its mannan and arabinan domains and phosphatidylinositol anchor.
The Mtb sucT mutant produces an AG devoid of succinyl substituents
The degree of succinylation of AG in Mtb sucT::Tn relative to the WT and complemented strains was determined by submitting purified mycolyl-AG-peptidoglycan (mAGP) complex to the same butanolysis procedure as for LAM [17–18]. This analysis revealed a dramatic decrease in the succinate content of the mutant mAGP which was partially or totally restored in the complemented mutants [Fig 2B]. The residual succinates in Mtb sucT::Tn mAGP are tentatively attributed to the activity of another succinyltransferase capable of succinylating the arabinan domain of AG or as yet unknown other positions of AG, peptidoglycan or mycolic acids. Analyses of the monosaccharide composition [S4 Table] and glycosyl linkages [S5 Table] of the WT, mutant and complemented mutant AG otherwise revealed near identical AG structures in all three strains. The degree of mycolylation of the mutant AG was also comparable to that of the WT and complemented mutant strains [S4 Table].
The succinyl substituents of LAM are required for the mannose capping of LAM by the decaprenyl phosphomannose-dependent mannosyltransferase, CapA
To probe the reasons underlying the loss of LAM mannoside caps in Mtb sucT::Tn, we next sought to determine whether succinylation of LAM governed the ability to the decaprenyl-phosphomannose-dependent mannosyltransferase CapA to mannosylate the non-reducing arabinan termini of LAM [25] [Fig 1]. This hypothesis was tested genetically by expressing Mtb capA in the backgrounds of M. abscessus WT and an M. abscessus mutant deficient in SucT activity. Like other rapidly growing mycobacteria, M. abscessus is naturally deficient in CapA activity, consistent with the fact that it produces a LAM devoid of any form of capping [18]. We reasoned that if succinylation of the non-reducing arabinan termini of LAM was required for CapA to add the first Manp residue of the cap in Mtb, then this enzyme should be active in M. abscessus WT which produces succinylated arabinan termini, but not in a M. abscessus sucT knock-out whose corresponding termini are devoid of succinyl substituents [18]. Both the WT and sucT mutant strains of M. abscessus were reported previously to display comparable relative abundances of β-2-linked Araf residues which serve as acceptors for the mannoside caps of LAM [18]. M. abscessus WT and ΔsucT were transformed with the capA expression plasmid pVV16-MT1671 [25,27]. The oligoarabinosides released by LAM purified from the capA-expressing WT and ΔsucT strains upon digestion with the Cellulomonas gelida endoarabinanase were next analyzed by LC/MS. The results which are presented in [Table 2] clearly pointed to the addition of mannoside caps containing up to three mannose residues onto the Ara4, Ara5 and Ara6 non-reducing arabinan termini of M. abscessus LAM in the WT strain expressing capA which were not detected in WT M. abscessus lacking the capA expression plasmid. Mannose-capping also occurred in the M. abscessus sucT mutant expressing capA, albeit at a much-reduced level compared to the capA-expressing WT strain. Indeed, mannosylated Ara4 and Ara6 oligoarabinosides in the capA-expressing mutant only occurred at 3% and 4.8% the levels observed in the capA-expressing WT strain, respectively, and no mannosylated Ara5 oligoarabinosides were formed in the mutant background. Thus, consistent with the finding of limited mannoside capping in the Mtb sucT::Tn mutant, the absence of LAM succinylation did not completely abolish the mannosylation of the non-reducing arabinan termini in M. abscessus ΔsucT expressing capA but drastically reduced the efficiency of CapA-mediated mannosyl transfer.
[Figure omitted. See PDF.]
Table 2. LC/MS analysis of the mannose capping of LAM in capA-expressing M. abscessus strains either proficient or deficient in LAM succinylation.
Shown in bold letters are the relative percentages of total (including, unmodified and covalently modified) Ara4, Ara5 and Ara6 oligoarabinosides released upon Cellulomonas gelida endoarabinanase digestion of LAM from M. abscessus WT and ΔsucT expressing or not capA (from pVV16-MT1671) and the individual representation (expressed as percentages) of unmodified and covalently modified oligoarabinosides within each group. Suc, succinate; Manx, mannoside cap containing x mannose residues.
https://doi.org/10.1371/journal.ppat.1011636.t002
Impact of AG and LAM succinylation on the growth, surface properties, and drug susceptibility of Mtb
The study by independent groups of sucT-deficient mutants of M. avium, M. smegmatis, M. marinum and M. abscessus has led to the conclusion that the loss of AG and LAM succinylation alters, in a species-specific manner, one or more of the following phenotypes reflective of the surface properties of the bacilli: colony morphology, surface hydrophobicity, biofilm-forming capacity, and propensity to aggregate in liquid broth [17–18,20–21]. While the sucT mutant of Mtb failed to show any obvious changes in colony morphology, acid-fast staining [S3A Fig] or surface hydrophobicity [S3B Fig], and did not hyper-aggregate in liquid broth, it grew at a slower rate than WT Mtb CDC1551 in laboratory medium [S3C Fig]. Complementation of the Mtb sucT mutant with a WT copy of the sucT gene expressed either from a replicative plasmid under control of the constitutive hsp60 promoter (Mtb sucT::Tn comp) or from an integrative plasmid under control of the same promoter (Mtb sucT::Tn comp-int), while working to restore the succinylation of LAM and AG [Fig 2], failed to restore WT growth [S3C Fig]. Although frameshift mutations in the glpK and ponA2 genes of the mutant and complemented mutant were identified by whole genome sequencing [S6 Table], it is unlikely that they contribute to the pronounced growth retardation of these strains in 7H9-ADC-Tween 80 medium (devoid of glycerol supplement) given that neither glpK or ponA2 null mutants display such growth defects under these conditions [28–30]. In the absence of additional secondary mutations in Mtb sucT::Tn comp-int relative to Mtb sucT::Tn that might have explained the lack of restoration of growth of the complemented mutant [S6 Table], we presently have no explanation for this phenotype other than suspecting improper or improperly regulated levels of expression of sucT in the complemented strain preventing WT growth in 7H9-ADC-Tween 80. Alternatively, the presence of a C-terminal hexahistidine tag on the SucT protein produced by the complemented strain may hamper its activity or ability to productively interact with other proteins. Of note, we experienced similar difficulties in trying to restore the axenic growth of M. smegmatis and M. abscessus sucT KO mutants upon genetic complementation (including with WT sucT orthologs devoid of His6-tag) [17–18]. Interestingly, a recent Tn-Seq study found the sucT gene to become critical to M. smegmatis growth when asymmetric cell elongation was impaired (i.e., upon disruption of the mycobacterial divisome factor, lamA) [31]. While no clear explanation was provided for this observation, this result points to an important impact either of cell envelope glycan succinylation or the presence of the SucT protein itself (e.g., as part of a multiprotein complex) during cell elongation and division and thus replicative growth.
Consistent with a previous report [32], drug susceptibility testing revealed a modest but reproducible 2-to 4-fold increase in the susceptibility of Mtb CDC1551 sucT mutant to imipenem and carbenicillin relative to the WT and complemented mutant strains [S7 Table]. Susceptibility to the two β-lactams reverted towards WT levels in the complemented mutant.
Immune responses induced by Mtb sucT::Tn in murine bone marrow-derived macrophages
We reported earlier on the reduced uptake and intracellular replication and survival of a M. abscessus sucT mutant compared to the WT parent and complemented mutant strains in macrophages and epithelial cells [18]. To investigate potential effects of AG and LAM succinylation on the interactions of Mtb with innate immune cells, mouse bone marrow-derived macrophages (BMMΦ) from C3HeB/FeJ mice were infected with WT Mtb CDC1551, the sucT mutant and the complemented mutant, and the different strains compared for their intracellular survival and ability to induce expression of innate immunity activation markers and chemokine/cytokine secretion. Accordingly, macrophages were infected with the three strains at an MOI of 5. Similar numbers of bacilli were recovered from infected macrophages 2 h after infection indicative of equivalent numbers of infecting Mtb strains [S4A Fig]. Determination of intracellular CFUs 5 days post-infection showed that the intracellular persistence of the sucT mutant was slightly but significantly less than that measured for the WT and complemented mutant strains [S4A Fig]. Interestingly, determination of the level of expression of macrophage antigen presentation/processing and activation markers (MHCII, CD80, CD86 and CD40) by flow cytometry after 48 h of infection [Fig 3A] revealed that all markers were significantly increased in cells infected with the sucT mutant. Cells infected with the Mtb sucT::Tn comp mutant, in contrast, demonstrated expression levels that were not significantly different from their WT counterparts [Fig 3A]. Analysis of chemokines revealed that, in comparison to infection with WT Mtb or Mtb sucT::Tn comp, secretion of IP-10, CXCL2, GROA (GRO-alpha) and RANTES were significantly increased with the sucT mutant, as was the secretion of key pro-inflammatory cytokines (TNFα, IL-6, IL1-β and IL-22), indicative of macrophages poised for increased proinflammatory state [Fig 3B]. Infection with the sucT::Tn mutant, when compared to Mtb WT, indicated no significant differences in expression of MCP-1, MCP-3 or CCL4. Finally, culture supernatants from cells infected with the sucT mutant presented significantly more nitric oxide (NO). This release of NO was comparable to levels observed in BMMΦ treated with LPS [Fig 3C].
[Figure omitted. See PDF.]
Fig 3. Evaluation of immune activation and chemokine/cytokine secretion by C3HeB/FeJ BMMΦ infected with Mtb CDC1551 WT, the sucT mutant and the complemented mutant strain.
C3HeB/FeJ BMMΦ were infected with either WT Mtb CDC1551, Mtb sucT::Tn (“SucT”) or Mtb sucT::Tn comp (“SucT comp”) and allowed to adhere for 2 h. Cells were washed to remove extracellular bacteria and subsequently harvested 48 h post-infection for activation marker, chemokine/cytokine and NO release analysis. (A) Levels of expression of activation markers for MHCII, CD80, CD86 and CD40 was determined by flow cytometry. (B) Culture supernatants were analyzed for chemokine/cytokine secretion by multiplex immunoassay using Luminex. (C) NO production was determined using the Griess Reagent test. Immune activation, chemokine/cytokine release and NO data for triplicate samples were analyzed using an ordinary one-way ANOVA with *p≤0.05, **p≤0.01, ***p≤0.005 and ****p≤0.001. Error bars represent the mean spanning the SD of each replicate. Experiment was repeated two times.
https://doi.org/10.1371/journal.ppat.1011636.g003
Innate immune responses induced by Mtb sucT::Tn in human primary macrophages
Similar trends as far as immune responses and intracellular survival were observed in infected human macrophages in vitro as was observed in murine BMMΦ [Figs 4 and S4B]. Compared to WT and/or Mtb sucT::Tn comp-infected cells, sucT mutant-infected monocyte-derived macrophages (MDM) differentiated from PBMC obtained from whole blood of healthy human donors consistently displayed significant increases in human antigen presentation/processing activation markers (HLA-DR, CD80, CD86 and CD40) [Fig 4A]. With the exception of CD40, expression levels of the same markers in cells infected with the complemented mutant were not significantly different from those measured in WT-infected cells. Interestingly, despite an overall lower CFU recovery from Mtb sucT::Tn-infected cells when compared to infection with WT Mtb (but comparable bacterial load to the complemented mutant) [S4B Fig], there was a significant increase in expression of the chemokine RANTES along with reductions of MCP-1. Pro-inflammatory cytokines (IL-6, IFNγ, TNFα, and IL-12p40) as well as the anti-inflammatory cytokine IL-13 increased, whereas release of IL-1Ra (an IL-1β inhibitor) was reduced by infection with the mutant strain [Fig 4B]. Genetic complementation largely resulted in release of chemokines and cytokines that were not significantly different from their cognate WT infection with the noted exceptions of IL-8, IL-6 and IL-1Ra that did not demonstrate expression levels comparable to WT [Fig 4B]. Finally, NO release in culture supernatants from MDM infected with the sucT mutant was significantly more pronounced compared to cells infected with WT Mtb or the complemented mutant strain [Fig 4C]. Overall, human macrophages released considerably less NO than was observed in the mouse BMMΦ, consistent with earlier observations.
[Figure omitted. See PDF.]
Fig 4. Evaluation of immune activation and chemokine/cytokine secretion by M-CSF-differentiated MDM infected with Mtb CDC1551 WT, the sucT mutant and the complemented mutant strain.
Human monocyte derived macrophages (MDM) were infected with either WT Mtb CDC1551, Mtb sucT::Tn (“SucT”) or Mtb sucT::Tn comp (“SucT comp”) for 2 h. Cells were then washed to remove extracellular bacteria and were subsequently harvested 48 h post-infection for activation marker, chemokine/cytokine and NO release analysis. (A) Levels of expression of activation markers for HLA-DR, CD80, CD86 and CD40 was determined by flow cytometry. (B) Cytokines and chemokines in culture supernatants were analyzed by multiplex immunoassay using Luminex. (C) NO secretion was determined by the Griess Reagent kit. Immune activation, chemokine/cytokine release and NO data for triplicate samples were analyzed using an ordinary one-way ANOVA with *p≤0.05, **p≤0.01, ***p≤0.005 and ****p≤0.001. Error bars represent the mean spanning the SD of each replicate. Experiment was repeated two times.
https://doi.org/10.1371/journal.ppat.1011636.g004
Collectively, results from human MDM are again consistent with the notion that strategically placed succinyl substituents in major cell envelope polysaccharides have an immunomodulatory function that promotes the establishment of Mtb infection by limiting or altering host pro-inflammatory and immune regulatory responses.
Discussion
The molecular processes leading to the assembly of AG, PIM, LM and LAM in the cell envelope are expected to be tightly regulated [9,33–37]. Whether minor covalent modifications of these glycans might act as molecular signals controlling their biosynthesis and export, as was shown with other prokaryotic polysaccharides, had not yet been established. In Gram-negative bacteria, the acylation, phosphorylation and L-Ara4N modification of lipid A are critical to the proper biosynthesis and/or export of this biosynthetic precursor to the periplasmic side of the plasma membrane, and the translocation of LPS to the outer membrane [7,38]. Likewise, modifications of the nonreducing terminal residues of O-antigen polysaccharides and S-layer glycans by methyl and phosphate groups is a well-established strategy used by a number of Gram-positive and Gram-negative microorganisms to control the chain length and export of polysaccharides assembled and exported through ABC-transporter-dependent pathways [39]. Precedents for the existence of similar regulatory processes in mycobacteria are scarce. The transient acetylation of the mycolic acid moiety of trehalose monomycolate by the essential acetyltransferase TmaT appears to be a prerequisite for the export of trehalose monomycolate to the periplasmic space of Corynebacteria and Mycobacteria [40–41]. Preliminary studies on the biosynthesis of mycobacterial cytoplasmic polysaccharides known as the methylglucose lipopolysaccharides suggest that the acylation of these glycans controls both the position at which the methylation of glucosyl residues occurs [42] and the fatty acid-binding properties of the end products [43]. The results of our capA expression studies in sucT-proficient and sucT-deficient M. abscessus strains represent the first example of a discrete covalent modification controlling, most likely through charge-mediated effects, one of the key aspects of the biosynthesis of Mtb LAM: The addition of terminal mannoside caps by the decaprenyl-phosphomannose-dependent mannosyltransferase, CapA.
Another critical role of SucT-mediated polysaccharide succinylation revealed by our macrophage infection studies is the impact this tailoring modification has on the interactions of Mtb with innate immune cells. The hyper-inflammatory phenotype of the sucT mutant in murine and human macrophages suggests that the succinylation of AG and/or LAM in Mtb has an anti-inflammatory function delaying the activation of immune responses and possibly promoting or ensuring survival of the bacilli.
Early studies aimed at determining the role of LAM in mycobacterial virulence showed that Mtb LAM is able to alter a number of macrophage and dendritic cell functions associated with protective immunity. The mannoside caps of LAM, in particular, were shown to have profound implications on the biological activities of the entire molecule and were thus proposed to play an important role in virulence and the control of inflammation [9,13–16]. Of note, these caps may themselves be substituted with an α(1→4)-linked methylthio-D-xylose (MTX) residue [44] [Fig 1] whose immunomodulatory and anti-oxidative properties have been proposed to further enhance bacterial survival during infection [45–47]. The majority of the biological properties of mannoside-capped LAM, however, were inferred from cell-free studies using purified LAM (as summarized in ref. [15]). It is not until the discovery of capA and the construction of capless capA mutants that it actually became possible to measure the contribution of mannoside-capped LAM to pathogenesis in the context of live bacteria. The outcome of these whole cell-based studies came as a surprise to the field when disrupting capA failed to show any clear effect on the survival and replication of M. marinum, M. bovis BCG or Mtb in macrophage and animal models of infection (zebrafish, C57BL/6 and BALB/c mice) [24,26,48]. Likewise, an analysis of the immune responses (TNF-α, IL-17, IFNγ, NO) induced by an Mtb capA-deficient mutant compared to the WT parent strain in mouse bone-marrow-derived macrophages and the lungs and spleens of infected BALB/c mice failed to reveal any significant differences between the two strains [48]. It was proposed that other mannosylated ligands at the cell surface of whole bacilli (e.g., polar forms of phosphatidylinositol mannosides, glycoproteins and other as yet unidentified cell envelope constituents that share with mannosylated LAM the same α(1→2)-linked oligomannoside appendage) or other modulators of phagosome-lysosome fusion may play a more important role or, at least, have the ability to compensate for the loss of LAM mannoside-capping in the interactions of mycobacteria with host cells [24,48]. An important outcome of the present study is the realization that the control of LAM mannose-capping in Mtb may in fact only occur in the context of the addition or removal of succinates to the arabinan domain as opposed to solely being controlled at the level of CapA expression or activity. If that is the case, the effect of losing mannoside caps on LAM may only become apparent (i.e., detectable by immune cells) when AG and LAM succinylation is concurrently decreased or lost, both covalent substituents acting synergistically to achieve a particular outcome during infection. The results of infection experiments with the sucT mutant, however, should be interpreted cautiously given the broader direct and indirect effects succinyl substituents may have on the overall charge of AG and LAM and, thus, cell surface and cell envelope properties of mycobacterial bacilli [17–18,20]. Indeed, it is possible that the hyperinflammatory phenotype of Mtb sucT::Tn results from more complex and multifactorial cell envelope-related changes than the only loss of mannoside and MTX caps on LAM. To begin to address the mechanisms underlying the hyperinflammatory phenotype of this mutant, future investigations will aim to compare the virulence and immunopathogenicity of sucT, capA and MTX mutants of Mtb in murine models of TB infection and determining whether succinylation affects the way mannose- and MTX-capped LAM and other immunologically active surface ligands are presented to immune cells.
Materials and methods
Bacterial strains and growth conditions
Mtb CDC1551 and M. abscessus ATCC 19977 were grown under agitation at 37°C in Middlebrook 7H9 medium supplemented with 10% albumin-dextrose-catalase (ADC) (BD Sciences) and 0.05% Tween 80, in minimal Sauton’s medium with 0.05% tyloxapol, or on Middlebrook 7H11 agar supplemented with 10% oleic acid-albumin-dextrose-catalase (OADC) (BD Sciences). Zeocin (100 μg mL-1), hygromycin (50 μg mL-1) and kanamycin (25 μg mL-1 for Mtb; 100 μg mL-1 for M. abscessus) were added to the culture media as needed. Mtb CDC1551 Mtb sucT::Tn was obtained from BEI Resources. For genetic complementation, the Mtb sucT gene PCR-amplified using primers Rv1565c.fw (5’- ccaattccatatgttgaccctgtcgccgcctc -3’) and Rv1565c.rv (5’- cccaagcttccaccagtcggtgttcgccgc– 3’) was cloned downstream of the hsp60 promoter in the replicative plasmid, pMVGH1 [49], yielding pMVGH1-Rv1565c. Alternatively, a WT copy of sucT was stably expressed under control of the hsp60 promoter from the integrative plasmid, pNIP40b [50]. To this end, the entire sucT gene, C-terminal His6 tag and hsp60 promoter were cut out from pMVGH1-Rv1565c with XbaI and HpaI restriction enzymes and cloned into the blunted XbaI site of pNIP40b. M. abscessus ΔsucT was reported earlier18. Mtb CDC1551 WT, Mtb sucT::Tn and Mtb sucT::Tn comp-int (mutant complemented with an integrative plasmid) were whole genome sequenced as described further in the text, and the results are presented in S6 Table.
Preparation and analysis of lipids, lipoglycans and arabinogalactan
Extraction of total lipids, lipoglycans and mycolyl-AG-peptidoglycan (mAGP) complex from Mtb followed the same procedures as we used earlier in the characterization of the M. smegmatis and M. abscessus sucT mutants [17–18]. Lipoglycans were purified by gel exclusion chromatography and analyzed by SDS-PAGE on commercial Novex 10–20% Tricine gels stained with periodic acid Schiff reagent.
Structural analyses of PIMs, lipoglycans and mAGP followed earlier procedures [17–18,51]. Briefly, 1 mg of mAGP, 50 μg of LM and 50 μg of LAM were used for permethylation and alditol acetates preparation and analyzed by GC/MS to determine monosaccharide composition and glycosyl linkage patterns. Succinates were analyzed and quantified by GC/MS analysis as their butyl succinate derivatives obtained from either 20 μg of purified LAM or 1 mg of mAGP. The presence of capping motifs at the non-reducing arabinan termini of LAM from Mtb and M. abscessus expressing capA was analyzed by LC/MS after digestion of LAM with Cellulomonas gelida endoarabinanase. The endoarabinanase digestion products of LAM were directly analyzed by ultra-performance liquid chromatography (UPLC) on an Atlantis T3 column (Waters) using Waters Acquity UPLC H-Class system coupled to a Bruker MaXis Plus QTOF MS instrument according to the method described by De et al. [10]. The identity of the digested products was further confirmed by UPLC analysis after their overnight reduction with 10 mg mL-1 NaBD4 in 1 M NH4OH in ethanol followed by their per-O-methylation. The presence of mannoside capping motifs at the non-reducing arabinan termini of LAM from the various Mtb and M. abscessus strains was also analyzed by capillary electrophoresis as described previously [52].
The fatty acids esterifying the mannosylated phosphatidyl-myo-inositol anchor of LM and LAM were analyzed as their fatty acid methyl esters (FAME) by GC/MS. Briefly, 100 μg of LM and LAM were methanolyzed in 100 μL of 3M methanolic HCl by heating at 80°C overnight and extracted with n-hexane:water (1:1). FAMEs were analyzed on a Thermo Scientific TRACE 1310 Gas Chromatograph paired with a Thermo Scientific TSQ 8000 Evo Triple Quadrupole GC-MS/MS. Samples were run on a 30 m x 0.25 mm x 0.25 μm Zebron ZB-5HT Inferno capillary column (Phenomenex) at an initial temperature of 60°C. The temperature was increased to 375°C at a ramp rate of 20°C min-1 and held for 5 min. Data handling was carried out using the Thermo Scientific Chromeleon Chromatography Data System software.
Mycolic acids released from mAGP by treatment with 2 M trifluoroacetic acid were quantified by LC/MS as described earlier [22] on an Agilent 1260 Infinity chromatograph equipped with a 2.1 mm × 150 mm (3.5 μm particle size) XBridge reverse phase C18 column (Waters) coupled to an Agilent 6224 time-of-flight (TOF) mass spectrometer. Data were analyzed using the Agilent MassHunter software. The same instrument and LC/MS method were used to analyze the PIM profile from Mtb total lipid extracts.
NMR experiments were performed at 303K with a cryo-probed Bruker DRX600 spectrometer (Karlsruhe, Germany) using 2D 1H-1H TOCSY and 1H-13C HMQC sequences previously reported [53]. Native molecules were dissolved in D2O and analyzed in 200 x 5 mm 535-PP NMR tubes. Proton and carbon chemical shifts are expressed in ppm downfield from the signal of external acetone (δH 2.22 and δC 30.89).
Acid-fast staining of Mtb bacilli
Bacteria were fixed with 1.5% formalin in 10% skim milk suspension and smeared on a microscope slide. The staining protocol followed the modified Kinyoun method and used TB Kinyoun Carbolfuchsin to stain the bacilli for 5 min, followed by decolorization with 3% HCl in ethanol, rinsing and counterstain with 0.3% methylene blue for 1 min.
Hydrophobicity index
Relative hydrophobicities were assessed by the hexadecane partition procedure [54]. Briefly, 1 OD 650 nm unit PBS-washed cell suspension of each strain was mixed with 0.3 mL hexadecane by vortexing for 2 min. The hydrophobicity index is defined as the percentage reduction in the OD650 nm of the aqueous phase after partitioning with the hydrocarbon phase.
Drug susceptibility testing
Minimum inhibitory concentration (MIC) values were determined in 7H9-OADC-tyloxapol in a total volume of 100 μL in 96-well microtiter plates. Mtb cultures grown to early log phase (OD600 nm ∼ 0.2) were diluted to OD600nm 0.01 and incubated in the presence of serial dilutions of the antibiotics for 10 days at 37°C. MICs were determined using the resazurin blue test [55].
Ethics statement
The Institutional Animal Care and Use Committee of Colorado State University approved all animal studies. Studies were performed in accordance with recommendations of the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health.
Preparation of mouse bone marrow macrophages
Six to eight weeks old C3HeB/FeJ female mice were purchased from The Jackson Laboratory (Bar Harbor. ME). Bone marrow cells were harvested from tibias and femurs of C3HeB/FeJ mice. Bone marrow cells were flushed from bones by snipping the head of the bones and placing them up-side-down in sterile 0.5-mL Eppendorf tubes (with a hole in bottom) inserted into a larger 1.0 mL Eppendorf tube. The bones within Eppendorf tubes were centrifuged 15 seconds at 10,000 x g and the bone marrow cells were collected at the bottom of the enveloped Eppendorf tube. The bone marrow cells were differentiated into macrophages by incubation in complete RPMI medium (cRPMI supplemented with 10% heat-inactivated FBS, recombinant M-CSF or GM-CSF [Peprotech; 15–20 ng/mL], 0.1% of 55 mM 2-mercaptoethanol, 1% penicillin-streptomycin (Gibco, Gaithersburg, MD), 0.3% Sodium Bicarbonate (Gibco), 0.8% L-glutamine, 1% essential amino acids solution (Gibco) and 1% non-essential amino acids solution (Gibco)). Primary cells were cultured for 7 days in 24-well plates with media changes every 2 days. Adherent cells were selected as mature macrophages (BMMΦs) for further studies and used at passage 1.
Procurement of human blood and preparation of MDM
Units of whole blood were obtained by under a material transfer agreement from the Garth England Blood Bank in Fort Collins. Whole blood was obtained from anonymous donors who have been deemed acceptable for blood donation through screening for Human Immunodeficiency Virus, and Human Hepatitis A, B and C. No blood was donated specifically for this work and was procured from the blood center as a quantity not sufficient (QNS) and suitable for clinical application and would otherwise be disposed. Hence, no Internal Review Board (IRB) requirement was necessary for the acquisition of these human blood specimens. Blood was centrifuged at 400 x g for 20 min and the top buffy coat was removed. The buffy coat was diluted 5-fold in sterile PBS and layered over a 10 mL pad of Ficoll-Paque PLUS (GE Healthcare Life Sciences, Pittsburgh, PA) and centrifuged again at 400 x g with the brake off. White blood cells (WBCs) were extracted from the interface, washed twice in Hanks Balanced Salt Solution (HBSS) and subsequently resuspended in DMEM containing 10% fetal bovine serum (FBS). PBMC were plated at 3.0–5.0×106 cells/mL in 24-well plates (CellTreat, Pepperell, MA) and monocytes were allowed to adhere to plastic for 2–3 h at 37°C. Monocytes were washed, counted and 1 mL of 15% FBS, 2% autologous donor serum containing growth factors was added. In total, differentiation medium was DMEM (Gibco/Life Technologies, Carlsbad, CA) containing 15% FBS, 1% penicillin-streptomycin (Hyclone, Logan, UT), 0.01M Hepes buffer (Hyclone, Logan, UT), 1 mM sodium pyruvate (Hyclone, Logan, UT), 1% MEM non-essential amino acids solution (Hyclone, Logan, UT)) and 30 ng/mL recombinant human M-CSF (R & D Systems, Minneapolis, MS). Monocytes were allowed to differentiate for 5–7 days (as determined by flow cytometric analysis of HLA-DR and morphological changes upon microscopic inspection). The differentiation medium was replaced every 48–72 h depending on the condition of the cells and pH of the culture.
Infection of human MDM and mouse bone marrow macrophages with Mtb
After 5–7 days of human monocyte differentiation to macrophages or mouse bone marrow differentiation to macrophages (BMMΦs), the DMEM was removed from the adherent cells and washed three times with pre-warmed PBS to remove the penicillin-streptomycin in the differentiation medium. All infection and harvesting procedures were performed in an approved BSL-3 facility. Log phase growth of Mtb strains were added to each well at an MOI of 5. Bacilli were resuspended in HBSS containing Mg++ and Ca++ and 2% autologous donor serum so that 250 μL of inoculum could be added to each well. Mouse BMMϕ were infected Mtb strains also at an MOI of 5 in 250 μl of complete DMEM without penicillin-streptomycin. The plates were briefly centrifuged for 5 min at 600 x g to facilitate bacillary interaction with either BMMΦ or MDM. In some cases, the cells were treated with 300 ng/mL LPS as a positive stimulatory control. At 2, 48 or 120 h, cells were washed thrice with PBS to remove the extracellular bacteria and either harvested for flow cytometry or lysed to count intracellular bacterial CFU by plating serial dilutions on 7H11-OADC agar plates.
Flow cytometric analysis of infected human MDM and mouse bone marrow macrophages
Following infection, BMMΦ or MDM were removed from the plate using ice cold PBS containing 5 mM EDTA. Cells were then transferred to a 96-well round bottom plate washed and stained for 20 min with fluorochrome-conjugated anti-mouse or anti-human MHCII, CD80, CD86 or CD40. The plate was then centrifuged and the cells washed then resuspended in PBS containing 4% PFA for 15 min. The plate was then centrifuged as above and cells washed with FACS staining buffer (PBS containing 2% FBS and 2 mM sodium azide). Expression of activation markers was determined using a Gallios flow cytometer (Beckman-Coulter, Brea, CA). List mode data (LMD) file data was analyzed using Flowjo software (Treestar Inc., Ashland, OR).
Multiplex immunoassay for cytokines and chemokines
Multiplex immunoassay using macrophage culture supernatants was performed using a Luminex bead-based multiplex ELISA kit (ProcartaPlex Mouse Cytokine & Chemokine Panel 1; 26plex, Invitrogen or MILLIPLEX Human Cytokine/Chemokine/Growth Factor Panel A, Millipore for MDM) according to the manufacturer’s instructions. Samples were fixed with 4% formaldehyde and subsequently washed prior to acquisition. Sample data were acquired on a MAGPIX instrument running xPONENT 4.3 software (Luminex Corp.) and analyzed using a five-parameter logistic model with an 80–120% standard acceptance range. Data was graphed using Graphpad Prism version 4.00.
Measurement of NO2- production
Nitric oxide release was measured from supernatants of macrophage cultures after 48 hours infected with the various Mtb strains or stimulated with LPS, using the Griess Reagent kit according to manufacturer’s protocol (Promega, Madison WI).
Statistical analysis
Unless otherwise indicated in the figure legends, data are expressed as the mean ± SD values from triplicate assays. The statistical tests used in the different experiments are indicated in the corresponding figure legends. Calculations were performed using Graphpad Prism version 4.00 for Windows (San Diego California USA). P-values <0.05 were considered significant.
Whole genome sequencing
Genomic DNA from Mtb CDC1551 WT, the sucT transposon mutant and the complemented mutant (Mtb sucT::Tn comp-int) was extracted from log-phase cultures grown in 7H9-ADC-Tween 80 using the Qiagen UCP Pathogen kit (Qiagen) following the manufacturer’s recommendations. Illumina libraries were prepared from 1 μg of mechanically fragmented DNA (300-bp, Covaris M instrument) using the Kapa HyperPrep kit as described previously [56] and quantified using the Qubit double-stranded DNA (dsDNA) BR assay kit (ThermoFisher Scientific). Fragments size was assessed on a Tape Station instrument (Agilent). Libraries were multiplexed and sequenced as 75-base-long single-end reads on an Illumina NextSeq 500 instrument. Reads were adapted and quality trimmed with Trimmomatic v0.33 [57] and mapped against the Mtb H37Rv reference genome (RefSeq NC_000962.3) and the plasmid used for complementation using Bowtie2 v2.2.5 [58]. Reads with mapping quality below 15 were filtered out, and duplicate reads were omitted from downstream analyses to avoid false SNP calls. SNP calling was done using VarScan v2.3.9 [59]. SNP calls were applied using the following cutoffs: minimum overall coverage of one non-duplicated read, minimum of five non-duplicated reads supporting the SNP, base quality score >15, and a SNP frequency above 80%. All VCF files were analyzed using SnpEff v5.0 [60] and the Mtb H37Rv annotation (RefSeq NC_000962.3). Vcf were merged using the component bcftools (option–merge) of the SAMtools package [61]. The sequencing data described in this publication have been submitted to the NCBI under BioProject # PRJNA991707.
Supporting information
S1 Table. Monosaccharidic composition of LM and LAM from WT Mtb, the sucT mutant and the complemented mutant strain.
Reported values are averages ± standard deviations of three technical repeats and represent relative distribution in %. The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c. Asterisks denote statistically significant differences between the WT and sucT mutant LM and LAM pursuant to the Student’s t-test (P < 0.05).
https://doi.org/10.1371/journal.ppat.1011636.s001
(PDF)
S2 Table. Glycosyl linkage analysis of per-O-methylated LM and LAM.
Reported values are averages ± standard deviations of three technical repeats and represent relative distribution in %. The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c. Asterisks denote statistically significant differences between the WT and sucT mutant LM and LAM pursuant to the Student’s t-test (P < 0.05).
https://doi.org/10.1371/journal.ppat.1011636.s002
(PDF)
S3 Table. Fatty acid composition of the mannosylated phosphatidyl-myo-inositol anchor of LM and LAM from WT Mtb, the sucT mutant and the complemented mutant strain.
Reported values represent relative distribution in %. C19: tuberculostearic acid. The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s003
(PDF)
S4 Table. Monosaccharidic composition of mAGP from WT Mtb, the sucT mutant and the complemented mutant strain.
Reported values are averages ± SD of three technical repeats and represent relative distribution in %. No statistically significant differences between strains were observed pursuant to the Student’s t-test (P > 0.05). The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s004
(PDF)
S5 Table. Glycosyl linkage analysis of per-O-methylated mAGP.
Reported values are averages ± SD of three technical repeats and represent relative distribution in %. No statistically significant differences between strains were observed pursuant to the Student’s t-test (P > 0.05). The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s005
(PDF)
S6 Table. Whole genome sequencing of WT Mtb CDC1551, the sucT transposon mutant and the complemented mutant strain, Mtb sucT::Tn comp-int.
https://doi.org/10.1371/journal.ppat.1011636.s006
(PDF)
S7 Table. Susceptibility of the Mtb sucT mutant to antibiotics.
MICs were determined in 7H9-OADC-tyloxapol using the resazurin blue test and MIC values are in μg mL-1. AMP, ampicillin; CRB, carbenicillin; CIP, ciprofloxacin; RIF, rifampicin; INH, isoniazid; GEN, gentamycin; EMB, ethambutol; STR, streptomycin; CAP, capreomycin; HYG, hygromycin; IMI, imipenem. MIC determinations were performed two to three times on independent culture batches. The sucT complemented mutant strain (Mtb sucT::Tn comp) is resistant to hygromycin due to the presence of complementation plasmid, pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s007
(PDF)
S1 Fig. Negative ion liquid chromatography-mass spectrometry (LC-MS) analysis of the oligoarabinosides released by the WT, the sucT mutant and the complemented mutant LAM upon digestion with the Cellulomonas gelida endoarabinanase.
Related to Table 1. Shown are extracted ion chromatograms (EICs) of the most abundant digestion products cleaved by Cellulomonas gelida endoarabinanase from the nonreducing end of LAM purified from the different strains. Several signals with identical exact masses for Ara4 (A) and Ara6 (D) oligosaccharides with m/z values of 545.1723 [M-H]− and 809.2569 [M-H]−, respectively, reveal the possibility of more structural isomers of tetra- and hexa-arabinoside termini in Mtb LAM. Ions corresponding to Ara4+succinate at m/z 645.1887 [M-H]− (B) and Ara6+succinate at m/z 909.2732 [M-H]− (E) are missing in the sucT mutant but were detected in the LAM purified from the WT and complemented mutant strains. The most abundant mannoside-capped digestion products from Mtb WT LAM are Man2Ara4 presented as [M-H]− ions at m/z 869.2780 (C), and Man4Ara6 presented as doubly charged [M-2H]−2 ions at m/z 728.2304 [M-2H]−2 (F). These ions were not detected in the sucT mutant but their presence was restored in the complemented mutant LAM. The complemented mutant strain used in this experiment (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s008
(PDF)
S2 Fig. PIM composition of Mtb CDC1551 WT, the sucT mutant and the complemented mutant strain.
(A) Thin-layer chromatography analysis of total lipids extracted from WT Mtb CDC1551, the sucT mutant and the complemented mutant strain. Total lipids were loaded on aluminum-backed silica gel 60-precoated plates F254 using chloroform:methanol:water (65:25:4; by vol.) as the eluent. TLCs were revealed by spraying with cupric sulfate (i) or α-naphthol (ii) and charring. The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c. (B) LC/MS analysis of PIM. Shown is the relative distribution of PIMs in WT Mtb CDC1551 (WT), the sucT mutant and the complemented mutant strain in %. PIM is used to describe the global family of phosphatidylinositol mannosides that carries one to four fatty acids (attached to the glycerol, inositol and/or mannose) and one to six mannose residues. In AcXPIMY, x refers to the number of acyl groups esterified to available hydroxyls on the mannose or myo-inositol residues, y refers to the number of mannose residues; e.g. Ac2PIM2 corresponds to the phosphatidylinositol dimannoside PIM2 carrying two acyl groups attached to the glycerol (the diacylglycerol substituent), one acyl group esterified to the mannose residue and one acyl group esterified to the myo-inositol residue. The complemented mutant strain (Mtb sucT::Tn comp) expresses WT sucT from pMVGH1-Rv1565c.
https://doi.org/10.1371/journal.ppat.1011636.s009
(PDF)
S3 Fig. Phenotypic characterization of Mtb sucT::Tn.
(A) Acid-fast staining of Mtb CDC1551 WT, the sucT mutant (sucT::Tn) and the complemented mutant strain (sucT::Tn comp). (B) Surface hydrophobicity of Mtb CDC1551 WT and the sucT mutant (sucT::Tn). Relative hydrophobicities were assessed by the hexadecane partition procedure as described in the Materials and Methods. The hydrophobicity index (H) is defined as the percentage reduction in the OD650 nm of the aqueous phase after partitioning with the hydrocarbon phase. The reported values are averages ± SD of three technical repeats. No statistically significant differences were noted between strains (P > 0.05; Student’s t-test). (C) Growth kinetics of WT Mtb CDC1551, Mtb sucT::Tn, Mtb sucT::Tn comp and Mtb sucT::Tn comp-int in 7H9-ADC-Tween 80 (no glycerol) at 37°C.
https://doi.org/10.1371/journal.ppat.1011636.s010
(PDF)
S4 Fig. Comparisons of Mtb CFU associated with C3HeB/FeJ BMMΦ and M-CSF-differentiated human MDM 2 hours and five days post-infection.
C3HeB/FeJ BMMΦ (from Fig 3) (A) and rM-CSF-differentiated human monocyte derived macrophages (MDM from Fig 4) (B) were infected with either WT Mtb CDC1551, Mtb sucT::Tn or Mtb sucT::Tn comp and allowed to adhere for 2 h. Macrophages were subsequently lysed 2 h and 120 h post-infection and lysates were plated on 7H11-OADC agar plates for CFU counting. Shown are averages and standard deviations for triplicate wells. Data were analyzed using ordinary two-way ANOVA with * p≤0.01, **p≤0.005 and ****p≤0.0001; ns, not significant.
https://doi.org/10.1371/journal.ppat.1011636.s011
(PDF)
S1 Data. Excel spreadsheet containing, in separate sheets, the underlying numerical data for Figs 2B, 2D, 3A, 3B, 3C, 4A, 4B, 4C, S3C, S4A and S4B.
https://doi.org/10.1371/journal.ppat.1011636.s012
(XLSX)
Acknowledgments
We thank the Integrated Screening Platform of Toulouse (PICT, IBiSA) for providing access to NMR spectrometers which were funded by CNRS, Université Paul Sabatier, Infrastructures en Biologie Santé et Agronomie (IBiSA), Région Occitanie and European Structural Funds. We thank Dr. Delphi Chatterjee and Anita Amin (Colorado State University) for the provision of Cellulomonas gelida endoarabinanase. The following reagent was obtained through BEI Resources, NIAID, NIH: Mycobacterium tuberculosis, Strain CDC1551, Transposon Mutant 2844 (MT1616, Rv1565c), NR-15460.
Citation: Palčeková Z, Obregón-Henao A, De K, Walz A, Lam H, Philp J, et al. (2023) Role of succinyl substituents in the mannose-capping of lipoarabinomannan and control of inflammation in Mycobacterium tuberculosis infection. PLoS Pathog 19(9): e1011636. https://doi.org/10.1371/journal.ppat.1011636
1. Maldonado RF, Sa-Correia I, Valvano MA. Lipopolysaccharide modification in Gram-negative bacteria during chronic infection. FEMS Microbiol Rev. 2016;40(4):480–93. pmid:27075488
2. Needham BD, Trent MS. Fortifying the barrier: the impact of lipid A remodelling on bacterial pathogenesis. Nat Rev Microbiol. 2013;11(7):467–81. pmid:23748343
3. Raetz CRH, Reynolds CM, Trent MS, Bishop RE. Lipid A modification systems in Gram-negative bacteria. Annu Rev Biochem. 2007;76:295–329. pmid:17362200
4. Rajagopal M, Walker S. Envelope Structures of Gram-Positive Bacteria. Curr Top Microbiol Immunol. 2017;404:1–44. pmid:26919863
5. Schneewind O, Missiakas D. Lipoteichoic acids, phosphate-containing polymers in the envelope of gram-positive bacteria. J Bacteriol. 2014;196(6):1133–42. pmid:24415723
6. Swoboda JG, Campbell J, Meredith TC, Walker S. Wall teichoic acid function, biosynthesis, and inhibition. Chembiochem: Chembiochem. 2010;11(1):35–45.
7. Whitfield C, Trent MS. Biosynthesis and Export of Bacterial Lipopolysaccharides. Annu Rev Biochem. 2014;83:99–128. pmid:24580642
8. Angala SK, Palčeková Z, Belardinelli JM, Jackson M. Covalent modifications of polysaccharides in mycobacteria. Nat Chem Biol. 2018;14(3):193–8. pmid:29443974
9. Angala SK, Belardinelli JM, Huc-Claustre E, Wheat WH, Jackson M. The cell envelope glycoconjugates of Mycobacterium tuberculosis. Crit. Rev. Biochem. Mol. Biol. 2014;49(5):361–99. pmid:24915502
10. De P, Shi L, Boot C, Ordway D, McNeil M, Chatterjee D. Comparative Structural Study of Terminal Ends of Lipoarabinomannan from Mice Infected Lung Tissues and Urine of a Tuberculosis Positive Patient. ACS Infect Dis. 2020;6(2):291–301. pmid:31762254
11. Angala SK, Joe M, McNeil MR, Liav A, Lowary TL, Jackson M. Use of Synthetic Glycolipids to Probe the Number and Position of Arabinan Chains on Mycobacterial Arabinogalactan. ACS Chem. Biol. 2021;16(1):20–6. pmid:33382235
12. Bhamidi S, Scherman MS, Jones V, Crick DC, Belisle JT, Brennan PJ, et al. 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. J Biol Chem. 2011;286(26):23168–77.
13. Ishikawa E, Mori D, Yamasaki S. Recognition of Mycobacterial Lipids by Immune Receptors. Trends Immunol. 2017;38(1):66–76. pmid:27889398
14. Torrelles JB, Schlesinger LS. Diversity in Mycobacterium tuberculosis mannosylated cell wall determinants impacts adaptation to the host. Tuberculosis (Edinb). 2010;90(2):84–93. pmid:20199890
15. Turner J, Torrelles JB. Mannose-capped lipoarabinomannan in Mycobacterium tuberculosis pathogenesis. Pathog Dis. 2018;76(4). pmid:29722821
16. Vergne I, Gilleron M, Nigou J. Manipulation of the endocytic pathway and phagocyte functions by Mycobacterium tuberculosis lipoarabinomannan. Front Cell Infect Microbiol. 2014;4:187. pmid:25629008
17. Palčeková Z, Angala SK, Belardinelli JM, Eskandarian HA, Joe M, Brunton R, et al. Disruption of the SucT acyltransferase in Mycobacterium smegmatis abrogates succinylation of cell envelope polysaccharides. J Biol Chem. 2019;294(26):10325–35.
18. Palčeková Z, Gilleron M, Angala SK, Belardinelli JM, McNeil M, Bermudez LE, et al. Polysaccharide Succinylation Enhances the Intracellular Survival of Mycobacterium abscessus. ACS Infect Dis. 2020;6(8):2235–48.
19. Delmas C, Gilleron M, Brando T, Vercellone A, Gheorghiu M, Rivière M, et al. Comparative structural study of the mannosylated-lipoarabinomannans from Mycobacterium bovis BCG vaccine strains: characterization and localization of succinates. Glycobiology. 1997;7:811–817
20. Driessen NN, Stoop EJ, Ummels R, Gurcha SS, Mishra AK, Larrouy-Maumus G, et al. Mycobacterium marinum MMAR_2380, a predicted transmembrane acyltransferase, is essential for the presence of the mannose cap on lipoarabinomannan. Microbiology. 2010;156(Pt 11):3492–502. pmid:20688818
21. Yamazaki Y, Danelishvili L, Wu M, Macnab M, Bermudez LE. Mycobacterium avium genes associated with the ability to form a biofilm. Appl. Environ. Microbiol. 2006;72(1):819–25. pmid:16391123
22. Bhamidi S, Scherman MS, Rithner CD, Prenni JE, Chatterjee D, Khoo K-H, et al. The identification and location of succinyl residues and the characterization of the interior arabinan region allows for a model of the complete primary structure of Mycobacterium tuberculosis mycolyl arabinogalactan. J Biol Chem. 2008;283(19):12992–3000.
23. Lamichhane G, Zignol M, Blades NJ, Geiman DE, Dougherty A, Grosset J, et al. A postgenomic method for predicting essential genes at subsaturation levels of mutagenesis: Application to Mycobacterium tuberculosis. Proc Natl Acad Sci USA. 2003;100(12):7213–8.
24. Appelmelk BJ, den Dunnen J, Driessen NN, Ummels R, Pak M, Nigou J, et al. The mannose cap of mycobacterial lipoarabinomannan does not dominate the Mycobacterium-host interaction. Cell Microbiol. 2008;10(4):930–44.
25. Dinadayala P, Kaur D, Berg S, Amin AG, Vissa VD, Chatterjee D, et al. Genetic basis for the synthesis of the immunomodulatory mannose caps of lipoarabinomannan in Mycobacterium tuberculosis J Biol Chem. 2006;281(29):20027–35.
26. Driessen NN, Ummels R, Maaskant JJ, Gurcha SS, Besra GS, Ainge GD, et al. Role of phosphatidylinositol mannosides in the interaction between mycobacteria and DC-SIGN. Infect Immun. 2009;77(10):4538–47. pmid:19651855
27. Kaur D, Obregón-Henao A, Pham H, Chatterjee D, Brennan PJ, Jackson M. Lipoarabinomannan of Mycobacterium; mannose capping by a multifunctional terminal mannosyltransferase. Proc Natl Acad Sci USA. 2008;105(46):17973–7.
28. Vandal OH, Pierini LM, Schnappinger D, Nathan CF, Ehrt S. A membrane protein preserves intrabacterial pH in intraphagosomal Mycobacterium tuberculosis. Nat Med. 2008;14(8):849–54. pmid:18641659
29. Pethe K, Sequeira PC, Agarwalla S, Rhee K, Kuhen K, Phong WY, et al. A chemical genetic screen in Mycobacterium tuberculosis identifies carbon-source-dependent growth inhibitors devoid of in vivo efficacy. Nat. Commun. 2010;1:57. pmid:20975714
30. Safi H, Gopal P, Lingaraju S, Ma S, Levine C, Dartois V, et al. Phase variation in Mycobacterium tuberculosis glpK produces transiently heritable drug tolerance. Proc Natl Acad Sci U S A. 2019;116(39):19665–74. pmid:31488707
31. Gupta KR, Gwin CM, Rahlwes KC, Biegas KJ, Wang C, Park JH, et al. An essential periplasmic protein coordinates lipid trafficking and is required for asymmetric polar growth in mycobacteria. Elife. 2022;11. pmid:36346214
32. Lun S, Miranda D, Kubler A, Guo H, Maiga MC, Winglee K, et al. Synthetic lethality reveals mechanisms of Mycobacterium tuberculosis resistance to beta-lactams. mBio. 2014;5(5):e01767–14.
33. Daffé M, Crick DC, Jackson M. Genetics of capsular polysaccharides and cell envelope (glyco)lipids. Microbiol Spectrum. 2014;2(4):MGM2–0021-2013.
34. Dulberger CL, Rubin EJ, Boutte CC. The mycobacterial cell envelope—a moving target. Nat Rev Microbiol. 2020;18(1):47–59. pmid:31728063
35. Guerin ME, Korduláková J, Alzari PM, Brennan PJ, Jackson M. Molecular basis of phosphatidyl-myo-inositol mannoside biosynthesis and regulation in mycobacteria. J Biol Chem. 2010;285(44):33577–83. pmid:20801880
36. Sena CBC, Fukuda T, Miyanagi K, Matsumoto S, Kobayashi K, Murakami Y, et al. Controlled expression of branch-forming mannosyltransferase is critical for mycobacterial lipoarabinomannan biosynthesis. J Biol Chem. 2010;285(18):13326–36. pmid:20215111
37. Shi L, Berg S, Lee A, Spencer JS, Zhang J, Vissa V, et al. The carboxy terminus of EmbC from Mycobacterium smegmatis mediates chain length extension of the arabinan in lipoarabinomannan. J Biol Chem. 2006;281(28):19512–26.
38. Hamad MA, Di Lorenzo F, Molinaro A, Valvano MA. Aminoarabinose is essential for lipopolysaccharide export and intrinsic antimicrobial peptide resistance in Burkholderia cenocepacia(dagger). Mol. Microbiol. 2012;85(5):962–74.
39. Cuthbertson L, Kos V, Whitfield C. ABC transporters involved in export of cell surface glycoconjugates. Microbiol. Mol. Biol. Rev. 2010;74(3):341–62. pmid:20805402
40. Belardinelli JM, Yazidi A, Yang L, Fabre L, Li W, Jacques B, et al. Structure-Function Profile of MmpL3, the Essential Mycolic Acid Transporter from Mycobacterium tuberculosis. ACS Infect Dis. 2016;2(10):702–13. pmid:27737557
41. Yamaryo-Botte Y, Rainczuk AK, Lea-Smith DJ, Brammananth R, van der Peet PL, Meikle P, et al. Acetylation of trehalose mycolates is required for efficient MmpL-mediated membrane transport in Corynebacterineae. ACS Chem. Biol. 2015;10(3):734–46. pmid:25427102
42. Grellert E, Ballou CE. Biosynthesis of a mycobacterial lipopolysaccharide. Evidence for an acylpolysaccharide methyltransferase. J Biol Chem. 1972;247(10):3236–41. pmid:5027750
43. Jackson M, Brennan PJ. Polymethylated polysaccharides from Mycobacterium species revisited. J Biol Chem. 2009;284(4):1949–53.
44. Turnbull WB, Stalford SA. Methylthioxylose—a jewel in the mycobacterial crown? Org. Biomol. Chem. 2012;10(30):5698–706. pmid:22575989
45. Chan J, Fan XD, Hunter SW, Brennan PJ, Bloom BR. Lipoarabinomannan, a possible virulence factor involved in persistence of Mycobacterium tuberculosis within macrophages. Infect Immun. 1991;59(5):1755–61.
46. Joe M, Sun D, Taha H, Completo GC, Croudace JE, Lammas DA, et al. The 5-deoxy-5-methylthio-xylofuranose residue in mycobacterial lipoarabinomannan. Absolute stereochemistry, linkage position, conformation, and immunomodulatory activity. J Am Chem Soc. 2006;128:5059–72. pmid:16608340
47. Stalford SA, Fascione MA, Sasindran SJ, Chatterjee D, Dhandayuthapani S, Turnbull WB. A natural carbohydrate substrate for Mycobacterium tuberculosis methionine sulfoxide reductase A. Chem Commun (Camb). 2009(1):110–2. pmid:19082015
48. Afonso-Barroso A, Clark SO, Williams A, Rosa GT, Nobrega C, Silva-Gomes S, et al. Lipoarabinomannan mannose caps do not affect mycobacterial virulence or the induction of protective immunity in experimental animal models of infection and have minimal impact on in vitro inflammatory responses. Cell Microbiol. 2013;15(4):660–74. pmid:23121245
49. Grzegorzewicz AE, Pham H, Gundi VA, Scherman MS, North EJ, Hess T, et al. Inhibition of mycolic acid transport across the Mycobacterium tuberculosis plasma membrane. Nat Chem Biol. 2012;8(4):334–41.
50. Mederle I, Bourguin I, Ensergueix D, Badell E, Moniz-Peireira J, Gicquel B, et al. Plasmidic versus insertional cloning of heterologous genes in Mycobacterium bovis BCG: impact on in vivo antigen persistence and immune responses. Infect Immun. 2002;70(1):303–14.
51. Sartain MJ, Dick DL, Rithner CD, Crick DC, Belisle JT. Lipidomic analyses of Mycobacterium tuberculosis based on accurate mass measurements and the novel Mtb LipidDB. J Lipid Res. 2011;52(5):861–72.
52. Nigou J, Vercellone A, Puzo G. New structural insights into the molecular deciphering of mycobacterial lipoglycan binding to C-type lectins: lipoarabinomannan glycoform characterization and quantification by capillary electrophoresis at the subnanomole level. J Mol Biol. 2000;299(5):1353–62. pmid:10873458
53. Gilleron M, Nigou J, Cahuzac B, Puzo G. Structural study of the lipomannans from Mycobacterium bovis BCG: characterisation of multiacylated forms of the phosphatidyl-myo-inositol anchor. J Mol Biol. 1999;285(5):2147–60.
54. Etienne G, Villeneuve C, Billman-Jacobe H, Astarie-Dequeker C, Dupont M-A, Daffé M. The impact of the absence of glycopeptidolipids on the ultrastructure, cell surface and cell wall properties, and phagocytosis of Mycobacterium smegmatis. Microbiology. 2002;148:3089–100.
55. Martin A, Camacho M, Portaels F, Palomino J-C. Resazurin microtiter assay plate testing of Mycobacterium tuberculosis susceptibilities to second-line drugs: rapid, simple, and inexpensive method. Antimicrob Agents Chemother. 2003;47(11):3616–9.
56. Avanzi C, Del-Pozo J, Benjak A, Stevenson K, Simpson VR, Busso P, et al. Red squirrels in the British Isles are infected with leprosy bacilli. Science. 2016;354(6313):744–7. pmid:27846605
57. Bolger AM, Lohse M, Usadel B. Trimmomatic: a flexible trimmer for Illumina sequence data. Bioinformatics. 2014;30(15):2114–20. pmid:24695404
58. Langmead B, Salzberg SL. Fast gapped-read alignment with Bowtie 2. Nat Methods. 2012;9(4):357–9. pmid:22388286
59. Koboldt DC, Zhang Q, Larson DE, Shen D, McLellan MD, Lin L, et al. VarScan 2: somatic mutation and copy number alteration discovery in cancer by exome sequencing. Genome Res. 2012;22(3):568–76. pmid:22300766
60. Cingolani P, Platts A, Wang le L, Coon M, Nguyen T, Wang L, et al. A program for annotating and predicting the effects of single nucleotide polymorphisms, SnpEff: SNPs in the genome of Drosophila melanogaster strain w1118; iso-2; iso-3. Fly (Austin). 2012;6(2):80–92. pmid:22728672
61. Li H. A statistical framework for SNP calling, mutation discovery, association mapping and population genetical parameter estimation from sequencing data. Bioinformatics. 2011;27(21):2987–93. pmid:21903627
About the Authors:
Zuzana Palčeková
Contributed equally to this work with: Zuzana Palčeková, Andrés Obregón-Henao, Kavita De
Roles: Conceptualization, Formal analysis, Investigation, Methodology, Writing – original draft, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Andrés Obregón-Henao
Contributed equally to this work with: Zuzana Palčeková, Andrés Obregón-Henao, Kavita De
Roles: Conceptualization, Formal analysis, Investigation, Methodology, Supervision, Writing – original draft, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Kavita De
Contributed equally to this work with: Zuzana Palčeková, Andrés Obregón-Henao, Kavita De
Roles: Formal analysis, Investigation, Writing – original draft, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Amanda Walz
Roles: Formal analysis, Investigation, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Ha Lam
Roles: Investigation, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Jamie Philp
Roles: Investigation, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Shiva Kumar Angala
Roles: Formal analysis, Investigation, Methodology, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Johnathan Patterson
Roles: Formal analysis
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Camron Pearce
Roles: Formal analysis, Investigation
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Sophie Zuberogoitia
Roles: Formal analysis, Investigation, Writing – review & editing
Affiliation: Institut de Pharmacologie et de Biologie Structurale, IPBS, Université de Toulouse, CNRS, UPS, Toulouse, France
Charlotte Avanzi
Roles: Formal analysis, Investigation
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Jérôme Nigou
Roles: Conceptualization, Formal analysis, Supervision, Writing – review & editing
Affiliation: Institut de Pharmacologie et de Biologie Structurale, IPBS, Université de Toulouse, CNRS, UPS, Toulouse, France
Michael McNeil
Roles: Formal analysis, Methodology, Supervision, Writing – review & editing
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Juan F. Muñoz Gutiérrez
Roles: Formal analysis, Investigation, Writing – review & editing
Affiliation: Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Martine Gilleron
Roles: Conceptualization, Formal analysis, Investigation, Writing – review & editing
Affiliation: Institut de Pharmacologie et de Biologie Structurale, IPBS, Université de Toulouse, CNRS, UPS, Toulouse, France
William H. Wheat
Roles: Conceptualization, Formal analysis, Investigation, Methodology, Supervision, Writing – original draft, Writing – review & editing
¶‡ WHW, MG-J and MJ contributed equally to this work as senior authors.
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Mercedes Gonzalez-Juarrero
Roles: Conceptualization, Formal analysis, Funding acquisition, Methodology, Project administration, Supervision, Writing – original draft, Writing – review & editing
¶‡ WHW, MG-J and MJ contributed equally to this work as senior authors.
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
Mary Jackson
Roles: Conceptualization, Data curation, Formal analysis, Funding acquisition, Project administration, Supervision, Writing – original draft, Writing – review & editing
* E-mail: [email protected]
¶‡ WHW, MG-J and MJ contributed equally to this work as senior authors.
Affiliation: Mycobacteria Research Laboratories, Department of Microbiology, Immunology and Pathology, Colorado State University, Fort Collins, Colorado, United States of America
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
© 2023 Palčeková et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Abstract
The covalent modification of bacterial (lipo)polysaccharides with discrete substituents may impact their biosynthesis, export and/or biological activity. Whether mycobacteria use a similar strategy to control the biogenesis of its cell envelope polysaccharides and modulate their interaction with the host during infection is unknown despite the report of a number of tailoring substituents modifying the structure of these glycans. Here, we show that discrete succinyl substituents strategically positioned on Mycobacterium tuberculosis (Mtb) lipoarabinomannan govern the mannose-capping of this lipoglycan and, thus, much of the biological activity of the entire molecule. We further show that the absence of succinyl substituents on the two main cell envelope glycans of Mtb, arabinogalactan and lipoarabinomannan, leads to a significant increase of pro-inflammatory cytokines and chemokines in infected murine and human macrophages. Collectively, our results validate polysaccharide succinylation as a critical mechanism by which Mtb controls inflammation.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer