Mycobacterium smegmatis Phosphoinositols-Glyceroarabinomannans
STRUCTURE AND LOCALIZATION OF ALKALI-LABILE AND ALKALI-STABLE PHOSPHOINOSITIDES*

(Received for publication, April 22, 1996, and in revised form, October 16, 1996)

Martine Gilleron , Nourrédine Himoudi , Olivier Adam , Patricia Constant , Anne Venisse , Michel Rivière and Germain Puzo Dagger

From the Institut de Pharmacologie et de Biologie Structurale du Centre National de la Recherche Scientifique, 118 route de Narbonne, 31062 Toulouse Cedex, France

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgment
REFERENCES


ABSTRACT

Lipoarabinomannans from fast growing Mycobacterium sp., namely AraLAMs, stimulate the early events of macrophage activation. The immunological activities of all of these AraLAMs drastically decrease with the loss of the mild alkali groups, which were believed to be restricted to the fatty acid residues from the phosphatidyl-myo-inositol anchor. This report reveals the presence and the structure of mild alkali-labile phosphoinositide units linked via the phosphate to the C-5 of the beta -D-Araf in the AraLAMs of Mycobacterium smegmatis, a fast growing mycobacterial species. Their structure was unambiguously established with a strategy based on both one-dimensional 31P and two-dimensional 1H-31P heteronuclear multiple quantum correlation spectroscopy (HMQC) and HMQC-homonuclear Hartmann-Hahn spectroscopy NMR experiments applied to native AraLAMs and to AraLAMs treated in mild alkali conditions. Next to these alkali-labile phosphoinositides estimated at three per molecule, two other mild alkali-stable phosphoinositide units were identified: the expected (myo-inositol-1)-phosphate-(3-glycerol) unit typifying the well known glycosylphosphatidylinositol anchor of the mannan core and, more surprisingly, one (myo-inositol-1)-phosphate-(5-beta -D-Araf) unit having the same structure as the alkali-labile ones. Moreover, these four phosphoinositide units were found capping the arabinan side chains. Thus, their different behavior toward mild alkaline hydrolysis was explained according to their accessibility to the alkali reagent. This novel class of LAMs, namely phosphoinositols-glyceroarabinomannans (PI-GAMs), are characterized by their phosphoinositide units but also by the absence of fatty acid residues. These PI-GAMs were found to elicit the secretion of tumor necrosis factor-alpha , suggesting that phosphoinositides are the major PI-GAM epitope involved in this process.


INTRODUCTION

In recent years, the immunological findings concerning lipoarabinomannans (LAMs)1 have indicated that they play a key role in tuberculosis immunopathogenesis (1). These lipopolysaccharide-like molecules are ubiquitously found in the cell walls of the Mycobacterium genus (2). According to their structure, LAMs have been classified into two types, the mannosylated LAMs, called ManLAMs, and the AraLAMs. ManLAMs are characterized by the presence of small alpha (1-2)-manno-oligosaccharides located at the arabinan side-chain termini. More recently, the ManLAMs have been subdivided into two types according to the presence or absence of phosphatidyl-myo-Ins anchor (3). ManLAMs were first isolated from the Mycobacterium tuberculosis Erdman strain (4, 5) and further from the vaccine strain Mycobacterium bovis BCG (6, 7). AraLAMs are devoid of manno-oligosaccharide caps, but the presence of myo-Ins phosphate units capping a minor portion of the AraLAM arabinan side chains was recently established (8). These AraLAMs arise from an unidentified fast growing mycobacterial strain that was initially considered as H37Ra (9).

AraLAMs mediate the early activation of macrophages. They stimulate early gene responses, at the mRNA level, of the c-fos gene and chemotactic JE and KC cytokines (10, 11), but they also induce transcription of the mRNA for cytokines characteristically produced by macrophages (tumor necrosis factor-alpha and interleukins 1-alpha , 1-beta , 6, 8, and 10). The TNF-alpha transcription induced by AraLAMs was blocked by monoclonal antibodies against CD14, an LPS receptor (12).

These AraLAM activities dramatically decrease when ManLAMs are used (10), in agreement with the fact that virulent organisms survive and multiply within the infected macrophages. However, ManLAMs mediate other major specific interactions between immune cells and mycobacteria. It was demonstrated that the ManLAMs from M. tuberculosis and M. bovis BCG bind selectively to murine and human macrophages through the mannose receptor (13, 14), suggesting that they mediate the binding of these mycobacteria to the alveolar macrophages. More recent data (15) indicate that double negative human CD4- CD8- alpha beta T-cell lines recognize ManLAMs from M. tuberculosis and Mycobacterium leprae presented by human CD1b molecules.

All these ManLAM and AraLAM properties disappear after mild alkaline treatment, revealing the key role of the alkali-labile residues (16, 17). To date, from the ManLAM and AraLAM structural models proposed, these alkali residues are restricted to the fatty acids of the myo-Ins phosphatidyl anchor. However, Hunter and Brennan (18) reported the existence of alkali-stable and alkali-labile myo-Ins in the LAMs from H37Ra. The alkali-stable myo-Ins was assigned to the phosphatidyl-myo-Ins anchor located at the nonreducing end of the mannan core. Its structure was completely elucidated by two-dimensional NMR 1H-31P heteronuclear multiple quantum correlation spectroscopy-homonuclear Hartmann-Hahn (HMQC-HOHAHA) experiments, unambiguously establishing that the anchor was part of the LAMs and not due to possible phosphatidylinositol mannoside contamination (3). However, the precise location of the alkali-labile myo-Ins phosphate residues as well as their substituent structures were unknown (18).

Mycobacterium smegmatis is a fast growing mycobacterial strain. A serologically active acidic arabinomannan was purified from M. smegmatis by Weber and Gray (19) and was fractioned into phosphorylated and nonphosphorylated molecules. Preliminary structural studies revealed that both forms have similar core structures characterized by 1right-arrow5-linked Araf residues attached to O-4 of Arap and 6-O-linked alpha -D-Manp residues. In the present work, we have undertaken to explore the structure of the LAMs from M. smegmatis obtained by solvent cell wall extraction, using NMR spectroscopy, and more particularly, we address the question of the existence of alkali-stable and alkali-labile myo-Ins phosphates, their substituent structures, and their locations.


EXPERIMENTAL PROCEDURES

Extraction and Purification of AraLAMs, Deacylation, and Subsequent Purifications

The extraction and purification of M. smegmatis ATCC 607 AraLAMs were performed as described previously for the ManLAMs from M. bovis BCG (6). The M. smegmatis native LAMs monitored by SDS-polyacrylamide gel electrophoresis show a broad band located around 30 kDa, indicating that LAMs were not contaminated by lipomannans.

dAraLAMs were prepared from the crude fraction containing lipoglycan, namely LAMs and lipomannans (60 mg) treated with 0.1 N NaOH for 2 h at 40 °C followed by gel filtration on a Bio-Gel G75 column eluted by 0.1 N CH3COOH. The dLAM fractions were characterized by GC after hydrolysis and derivatization by a molar ratio of Ara to Man of 1.45:1.

Native AraLAMs (10 mg) were submitted to mild alkaline hydrolysis (0.1 N NaOD at 40 °C) in an NMR tube, and the reaction was monitored at different times (30 min, 1 h, 1 h 30 min, and 2 h) by 31P one-dimensional NMR spectroscopy. Then partial acidic hydrolysis of the dAraLAMs was performed with 0.06 N HCl for 15 min at 100 °C, and the hydrolysate after cooling was applied on a Bio-Gel P-4 column eluted by water. The collected samples were characterized by gas-liquid chromatography after hydrolysis (2 N trifluoroacetic acid for 2 h at 100 °C) and TMS derivatization.

Native AraLAMs (5 mg) were submitted in a NMR tube to partial acidic hydrolysis (0.1 N DCl for 15 min at 80 °C). The reaction was monitored by one-dimensional 31P NMR. The products of the reaction were then submitted to mild alkaline hydrolysis (0.1 N NaOD for 1 h at 40 °C) with no intermediate purification.

AraLAMs were O-methylated three times according to a modified (6) procedure of Ciucanu and Kerek (20). Per-O-methylated LAMs were hydrolyzed with 2 N trifluoroacetic acidic at 120 °C for 2 h, reduced with NaBD4, and acetylated. The alditol acetates were identified by GC/MS and quantified by GC. Table I reveals the presence per LAM molecule of the same ratio of t-Araf units and 3,5-di-O-linked Araf units.

Table I.

Methylation analysis of AraLAMs from M. smegmatis


Full name of the partially methylated alditol acetate derivative Abbreviated name of the glycosyl residue LAMa

mol%
2,3,5-Tri-O-Me-1,4-di-O-Ac-arabinitol t-Araf 11
3,5-Di-O-Me-1,2,4-tri-O-Ac-arabinitol 2-O-Linked Araf 9
2,3-Di-O-Me-1,4,5-tri-O-Ac-arabinitol 5-O-Linked Araf 45
2-O-Me-1,3,4,5-tetra-O-Ac-arabinitol 3,5-Di-O-linked Araf 11
2,3,4,6-Tetra-O-Me-1,5-di-O-Ac-mannitol t-Manp 12
2,3,4-Tri-O-Me-1,5,6-tri-O-Ac-mannitol 6-O-Linked Manp 5
3,4-Di-O-Me-1,2,5,6-tetra-O-Ac-mannitol 2,6-Di-O-linked Manp 7

a  Average values from three experiments.

Routine gas chromatography was performed on a Girdel series 30 chromatograph equipped with an OV1 wall-coated open tubular capillary column (25-m length × 0.22-mm inner diameter; Spiral, Dijon, France) using helium gas at a flow rate of 2.5 ml/min with a flame ionization detector at 310 °C. A temperature program from 100 to 280 °C at a speed of 3 °C/min was used. The injector temperature was 260 °C for TMS glycoside analysis. GC/MS analysis was performed on a Hewlett-Packard 5889X mass spectrometer (electron energy, 70 eV) working in both electron impact and chemical ionization modes, coupled with a Hewlett-Packard 5890 gas chromatograph series II fitted with an OV1 column (12 m × 0.30 mm).

NMR spectra were recorded on a Bruker AMX-500 spectrometer equipped with an Aspect X32 computer. Samples were exchanged in D2O (Spin et Techniques, Paris, France; 99.9% purity) with intermediate lyophilization and then dissolved in 99.96 atom % D2O at a concentration of 40 mg/ml for the native LAMs and 6 mg/ml for the dLAMs and analyzed in a 200 × 5-mm 535-PP NMR tubes. 1H Chemical shifts are expressed in ppm downfield from the signal for internal 3-(trimethylsilyl)-propane sulfonic acid sodium salt (delta H/TMS 0.015).

The one-dimensional proton (1H) spectrum was measured using a 30-90° tipping angle for the pulse and 1 s as a recycle delay between each of the 256 acquisitions of 1.64 s. The spectral width of 5005 Hz was collected in 16,000 complex points that were multiplied by an exponential function (LB = 2 Hz) prior to processing to 32,000 real points in the frequency domain. After Fourier transformation, the spectra were base line-corrected with a fourth order polynomial function.

The one-dimensional phosphorus (31P) spectra were measured at 202 MHz by employing a spectral width of 25 kHz, and phosphoric acid (85%) was used as the external standard (delta P 0.0). The data were collected in 32,000 complex data sets, and an exponential transformation (LB = 5 Hz) was applied prior to processing to 64,000 real points in the frequency domain.

All two-dimensional NMR data sets were recorded at 35 °C without sample spinning, and data were acquired in the phase-sensitive mode using the time-proportional phase increment (TPPI) method (21).

The two-dimensional HOHAHA spectrum was recorded using a MLEV-17 mixing sequence of 30 ms (22). The spin-lock field strength corresponded to a 90° pulse width of 30 µs. The spectral width was 5000 Hz in each dimension. The HOD signal was presaturated for 1 s during the relaxation delay. 1024 spectra of 4096 data points with 16 scans/t1 increment were recorded.

1H-31P and 1H-13C correlation spectra were recorded in the proton-detected mode with a Bruker 5-mm 1H broad band tunable probe with reversal geometry. The single-bond correlation spectra (HMQC) of 1H-13C and 1H-31P were obtained according Bax's pulse sequence (23). The GARP sequence (24) at the carbon or phosphorus frequency was used as a composite pulse decoupling during acquisition. For the 1H-13C HMQC spectrum, spectral widths of 16,250 Hz in 13C and 4500 Hz in 1H dimensions were used to collect a 4096 × 400 (TPPI) point data matrix with 32 scans/t1 value expanded to 4096 × 1024 by zero filling. The relaxation delay was 1.2 s. A sine bell window shifted by pi /2 was applied in both dimensions. The 1H-31P HMQC spectrum was obtained with a 4096 × 80 (TPPI) point data matrix with 64 scans/t1 value. The spectral window was 4003 Hz in F2 dimension (1H) and 810 Hz in F1 dimension (31P). Relaxation delay was 1.2 s. The original data matrix point was expanded to a 4096 × 512 real matrix. The pulse sequence used for 1H-detected heteronuclear relayed spectra (HMQC-HOHAHA) 1H-31P was that of Lerner and Bax (25). These spectra were obtained with a 4096 × 80 (TPPI) point data matrix with 64 scans/t1 value. The spectral window was 4003 Hz in F2 dimension (1H) and 810 Hz in F1 dimension (31P). The relaxation delay was 1.2 s, and different experiments were realized with different mixing times. The original data matrix was expanded to a 4096 × 512 real matrix.

TNF-alpha Assay

THP-1 monocyte/macrophage human cell line was maintained as nonadherent cells in continuous culture with Iscove's modified Dulbecco's medium (Life Technologies, Inc.), 10% fetal calf serum (Life Technologies) in an atmosphere of 5% CO2 at 37 °C. The purified molecules were added in duplicate to THP-1 cells (0.5 × 106 cells/well) in 24-well tissue culture plates and then incubated for 6 h at 37 °C. Stimuli were previously incubated 1 h at 37 °C in the presence or absence of 10 µg/ml polymyxin B (Sigma) known to inhibit the effect of LPS (26). Culture supernatants were then assayed for TNF using the previously described cytotoxic assay against WEHI164 clone 13 cells (27). Each supernatant was tested at two dilutions (1:2 and 1:20) in duplicate. The assay was performed as follows. 50 µl of sample were added to 50 µl of WEHI cells (4 × 105 cells/ml) in flat-bottom 96-well plates. In each experiment, a reference curve was obtained using serial dilutions of human recombinant TNF-alpha (Life Technologies) starting at 5000 down to 1 pg/ml. After a 20-h incubation at 37 °C, 50 µl of tetrazolium salts (1 mg/ml 3-(4,5-dimethyl thiazol-2-yl)-2,5-diphenyl tetrazolium bromide in Iscove's modified Dulbecco's medium, Sigma) were added to each well and incubated for 4 h. Formazan crystals were solubilized with 100 µl of lysis buffer (N,N-dimethyl formamide, 30% SDS (1:2) adjusted at pH 4.7 with acetic acid), and optical density was read at 570 nm with an enzyme-linked immunosorbent assay plate reader.


RESULTS

Determination of the M. smegmatis LAM Class

Fig. 1A presents the J-modulated 13C one-dimensional spectrum of the LAMs from M. smegmatis treated in mild alkaline conditions called dLAMs. This spectrum shows the same anomeric carbon resonances as those present in the partial DEPT 13C one-dimensional spectrum of the M. bovis BCG dLAMs (Fig. 1B). However, they differ by their relative intensity in the anomeric as well as in the exocyclic aliphatic carbon regions (not shown). First, the resonances at 103.42 ppm (V1) and 65.77 ppm (V5) (Fig. 1A), assigned to the C-1 and C-5 of t-beta -Arafs, are relatively more intense than those of the analogous carbons of the M. bovis BCG dLAMs, so the M. smegmatis LAMs contain relatively more t-beta -Araf units than the M. bovis BCG ones. The second major difference is the decrease of the anomeric carbon resonance intensity at delta  101.01 (VII1) (Fig. 1A) assigned to 2,6-di-O-linked alpha -Manps and maybe to 2-O-linked alpha -Manps, the latter of which are the ManLAM reporter units. In order to clarify this assignment, the M. smegmatis dLAM 1H-13C HMQC spectrum was recorded (Fig. 2). The C-1 resonance at delta 101.01 (VII1) correlated with one anomeric proton signal at 5.12 ppm, while in the M. bovis BCG dManLAM HMQC spectrum (6), this C-1 resonance correlated with two H-1 signals at 5.25 and 5.22 ppm. These protons were assigned to the H-1s of 2,6-di-O-linked alpha -Manps and 2-O-linked Manps corresponding, respectively, to the Manps from the mannan core and from the manno-oligosaccharide caps. So these data unambiguously reveal the absence of 2-O-linked Manp units in the LAMs of M. smegmatis. Likewise, a single correlation was observed between the M. smegmatis dLAM t-Manp C-1 resonance at 104.93 ppm (IV1) and the anomeric proton at 5.06 ppm. In the case of the M. bovis BCG LAMs, this anomeric carbon correlated with two H-1 signals assigned to the t-Manps from the mannan core and the manno-oligosaccharide caps. So, this result demonstrates that M. smegmatis LAMs contain a single type of t-Manps restricted to the mannan core. Thanks to the 1H-13C HMQC comparative analysis, we propose that the M. smegmatis LAMs are devoid of alpha -Manp-(1right-arrow[2)-alpha -Manp(1right-arrow]n (0 < n < 2) oligosaccharides capping the arabinan side chains and thus belong to the AraLAM class.


Fig. 1. A, J-modulated 13C one-dimensional spectrum of the dLAMs from M. smegmatis. B, expanded zone (delta  13C 87.5-113.0) of the DEPT 13C one-dimensional spectrum of the dLAMs from M. bovis BCG. Glycosyl residues are labeled in roman numerals, and their carbons are labeled in arabic numerals. I, 5-O-linked alpha -Araf; II, 3,5-di-O-linked alpha -Araf; III, 2-O-linked alpha -Araf; IV, t-alpha -Manp; V, t-beta -Araf; VI, 6-O-linked alpha -Manp; VII, 2-O-linked and 2,6-di-O-linked alpha -Manp.
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Fig. 2. Expanded region (delta  1H 4.85-5.33; delta  13C 100.0-111.5) of the 1H-13C HMQC spectrum of M. smegmatis dLAMs. Glycosyl residues are labeled in roman numerals, and their carbons are labeled in arabic numerals. I, 5-O-linked alpha -Araf; II, 3,5-di-O-linked alpha -Araf; III, 2-O-linked alpha -Araf; IV, t-alpha -Manp; V, t-beta -Araf; VI, 6-O-linked alpha -Manp; VII, 2,6-di-O-linked alpha -Manp.
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AraLAM Phosphorylation State

The native AraLAMs were analyzed by one-dimensional 31P NMR spectroscopy (Fig. 3). The one-dimensional 31P spectrum shows two distinct resonances at -0.11 ppm (P1) and -0.35 ppm (P2) with an integration ratio P2:P1 of 4. The P2 and P1 chemical shifts, which are not significantly affected by shifting the pD value from 6 to 10, were assigned to phosphodiester groups (28). The P1 resonance was tentatively assigned to the anchor phosphate based on the phosphate chemical shift (-0.1 ppm) of the phosphatidyl-myo-Ins anchor of M. bovis BCG ManLAMs (3). Moreover, from a previous study the mild alkali-stability of this phosphodiester linkage was established (3). Then, in order to support the P1 assignment, the AraLAMs were submitted to mild alkaline hydrolysis (0.1 N NaOD, 40 °C), and the reaction products were monitored by one-dimensional 31P NMR spectroscopy. After 30 min of mild alkaline hydrolysis (Fig. 4B), the P2:P1 ratio value decreases from 4 (Fig. 4A) to approximately 1 and remains constant with longer reaction times: 30 min (Fig. 4B) and 2 h (Fig. 4C). These data highlight the presence of three mild alkali-labile phosphate units (P2) and two mild alkali-stable phosphates (P1 and P2). One of the alkali-stable phosphate, probably P1, can be assigned to the anchor phosphate, but the presence of a supplementary and unexpected P2 alkali-stable resonance makes this P1 assignment hazardous. So, to demonstrate the P1 attribution and also to establish the substituent structure of the novel P2 alkali-stable unit, the AraLAMs treated in mild alkaline conditions, namely dAraLAMs, were analyzed by two-dimensional 1H-31P HMQC (Fig. 5b) and 1H-31P HMQC-HOHAHA (Fig. 5c) experiments. The 1H-31P HMQC sequence allows the assignment of the protons borne by the carbons involved in the phosphodiester linkage, while the 1H-31P HMQC-HOHAHA sequence leads to the definition of the substituent spin systems.


Fig. 3. One-dimensional 31P NMR spectrum (delta  31P -1.0-0.5) of the native M. smegmatis AraLAMs. The spectrum was recorded in D2O at pH 7.1 and 308 K (ns 1440, SW 6 ppm).
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Fig. 4. One-dimensional 31P NMR spectra (delta  31P -1.00-1.00) of M. smegmatis AraLAMs (A) and after 30 min (B) and 2 h (C) of mild alkali hydrolysis (0.1 N NaOD, 40 °C). The spectra were recorded in D2O at pH 8.5 and 313 K (ns 100, SW 15 ppm).
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Fig. 5. Partial 1H-1H two-dimensional HOHAHA (a) region (delta  1H 3.20-5.30 and 3.34-3.44) spectrum showing the Ins spin systems. Expanded region (delta  1H 3.20-5.30; delta  31P -0.57-0.08) of the 31P-decoupled, 1H-detected HMQC (b) and 63-ms HMQC-HOHAHA (c) spectra of dAraLAMs are shown. Numerals correspond to the proton number of the two myo-Ins units.
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Substituent Structure of the Two Mild Alkali-stable Phosphates, P1 and P2

The dAraLAM 1H-31P HMQC spectrum (Fig. 5b) provides correlations between the P1 resonance and three well-defined proton resonances at delta  4.16, delta  4.00, and delta  3.94. Since these protons resonate in an overcrowded area, their assignments based on chemical shifts remain hazardous. To overcome this problem, 1H-31P HMQC-HOHAHA spectra were performed with different mixing times. Using a long mixing time (63 ms) (Fig. 5c), the spectrum shows a complex set of correlations. However, the cross-peak at delta  3.39 reveals a well resolved proton resonance correlating on the HOHAHA spectrum (Fig. 5a) with five protons whose chemical shifts and multiplicities agree with a 1-phospho-myo-Ins spin system (Table II). In Table II, it can be seen that the myo-Ins H-1 (delta  4.16), H-2 (delta  4.35), and H-6 (delta  3.87) are downfield-shifted compared with those of the 1-phospho-myo-Ins standard, in agreement with the glycosylation of the myo-Ins at the C-6 by the mannan core and at the C-2 by one single alpha -D-Manp unit. Moreover, the P1 linkage to the myo-Ins C-1 was supported by the fact that H-1 (delta  4.16) resonates as a pseudodoublet and as a pseudotriplet in the 1H-31P decoupled HMQC-HOHAHA and in the HOHAHA spectra, respectively. The remaining delta  4.00 and delta  3.94 protons from the HMQC spectrum (Fig. 5b) were assigned to the glycerol prochiral H-3 and H-3', while H-1 and H-1' are defined from the HMQC-HOHAHA spectrum (Fig. 5c) at 3.70 and 3.73 ppm. The weak intensity cross-peak observed at 3.96 ppm on the HMQC-HOHAHA spectrum, using a short mixing time, reveals a connectivity between P1 and Gro H-2. As expected, it is now clearly established that the alkali-stable P1 corresponds to the phosphate unit of the glycosylphosphatidylinositol anchor.

Table II.

myo-Ins proton assignment


Signal  delta
Ja
Multiplicity  delta myo-Ins 1Pb
P1 P2 P1 P2

ppm Hz ppm
H-1 4.16 3.99 J1,2 2.2 2.0 Pseudotriplet 3.90
H-2 4.35c 4.27 J2,3 2.2 2.0 Pseudosingulet 4.23
H-3 3.61 3.57 J3,4 9.2 9.9 Pseudodoublet 3.58
H-4 3.67 3.67 J4,5 9.2 9.4 Triplet 3.64
H-5 3.39 3.34 J5,6 9.6 9.6 Triplet 3.34
H-6 3.87c 3.77 J6,1 9.6 9.7 Triplet 3.74

a  J1,P values of 9.6 (P1) and 9.7 Hz (P2) were measured on the HOHAHA spectrum.
b  Data from Refs. 37 and 38.
c  The substantial downfield shift (0.1 ppm) suggests that these positions are glycosylated.

The same NMR approach was applied in order to determine the substituent structure of the unexpected alkali-stable P2 resonance. As for P1, the HMQC spectrum shows that P2 correlates with three proton resonances at 4.14, 4.04, and 3.99 ppm (Fig. 5b). The HMQC-HOHAHA experiment reveals a complex pattern of connectivities. Again, the proton at 3.34 ppm, which resonates independently in the one-dimensional 1H spectrum, is attributed to H-5 from a second myo-Ins spin system (delta  H-1 3.99; delta  H-2 4.27; delta  H-3 3.57; delta  H-4 3.67; delta  H-5 3.34; delta H-6 3.77) (Fig. 5a). Likewise, P2 was found to esterify the second myo-Ins unit at the C-1 position from the multiplicity of H-1 (t, J1,P = J1,6 9.7 Hz) in the HOHAHA spectrum (Fig. 5a). The H-1, H-2, and H-6 protons are upfield-shifted compared with those of P1 myo-Ins resonating at chemical shifts comparable with those of the 1-phospho-myo-Ins standard, establishing that positions C-2 and C-6 are not glycosylated (Table II). Therefore, the P2 myo-Ins unit is localized at the terminal position. The remaining P2 proton connectivities (delta  4.14, delta  4.04) in the HMQC spectrum (Fig. 5b) can be attributed to geminal protons from an undetermined unit. From the 1H-31P HMQC-HOHAHA spectrum (Fig. 5c) a cross-peak with a proton at 5.16 ppm is observed assigned to an anomeric resonance either of 2,6-di-O-linked alpha -Manp or of t-beta -Araf. The J1,2 coupling constant value of 3.15 Hz (Fig. 6) typifies a beta -Araf unit (expected J1,2 of alpha -Manp and beta -Araf of 1.8 and 4.1 Hz (29), respectively). Therefore, the resonances at delta  4.14 and delta  4.04 were attributed to the geminal H-5/H-5' protons of a beta -Araf unit, revealing that P2 esterifies this unit at the C-5. This C-5 phosphoester linkage is also supported by the downfield chemical shifts of the H-5/H-5' (delta  H-5/H-5' alpha -L-Araf 3.80/3.68 (30)). In the 1H-31P HMQC-HOHAHA spectrum (Fig. 5c), the remaining cross-peak (delta 4.19) is in agreement with the chemical shift of the H-2, H-3, and H-4 alpha -Araf ring protons (delta  H-2 4.04, H-3 3.93, H-4 4.03) (30). Also, the subspectrum at delta  -0.35 (Fig. 6) reveals an extra beta -Araf ring proton resonance superimposed with the H-5 at 4.04 ppm. Thus, it is proposed that the mild alkali-stable P2 esterifies a terminal myo-Ins at the C-1 position and a beta -D-Araf at the C-5 position.


Fig. 6. Subspectrum of the 31P-decoupled, 1H-detected 200 ms HMQC-HOHAHA spectrum of dAraLAMs at delta  -0.35. The sweep widths were set to 1841 Hz in F2 dimension and 1012 Hz in F1 dimension. The data matrix point used was 4096 × 80 with 128 transients for each t1 increment. The data matrix was zero-filled to 4096 × 1024 points and multiplied by a pi /2 sine-bell function in both dimensions before Fourier transformation. H1-H6 correspond to the protons of the myc-Ins unit.
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To support the structure of the (beta -Araf-5)-P2-(1-t-myo-Ins) motif, the dAraLAMs were hydrolyzed in mild acidic conditions (0.06 N HCl, 15 min, 100 °C). The reaction products were chromatographed on a Bio-Gel P4 eluted with water and monitored for changes in refractive index. The chromatogram (Fig. 7A) shows mainly two peaks. The included sample (I) was hydrolyzed (2 N trifluoroacetic acid, 2 h, 100 °C) and was found by GC analysis to be composed almost exclusively of Araf, arising as expected from the arabinan moiety. The void volume (E) was subdivided into five fractions (fractions 12-16). By 31P one-dimensional NMR analysis, P1 was found in fractions 13 and 14, both P1 and P2 in fraction 15, and P2 alone in fraction 16 (Fig. 7B). This last fraction analyzed by GC after acidic hydrolysis reveals Araf and myo-Ins. Moreover, the two-dimensional HOHAHA experiment established that P2 esterifies a terminal myo-Ins unit (delta  H-1 3.99; delta  H-2 4.27; delta  H-3 3.57; delta  H-4 3.67; delta  H-5 3.34; delta H-6 3.77) (not shown). After peracetylation, fast atom bombardment-MS analysis in the negative mode (not shown) demonstrated from the pseudomolecular ions (M-H)- at m/z 727 that the major molecular species is Ara-P2-myo-Ins. Other pseudomolecular ions are observed in low abundance at m/z 943, 1159, 1375, and 1591, indicating that myo-Ins-P2 is also esterified by (Ara)n units, where n = 2-5, respectively.


Fig. 7. A, Bio-Gel P-4 chromatography of the dAraLAM hydrolysate (0.06 N HCl, 15 min, 100 °C) eluted with water. The peak corresponding to the void volume (E) was collected in different fractions. B, one-dimensional 31P NMR spectra (delta  31P -3.00-3.00) of the indicated void volume fractions. The spectra were recorded in D2O at pH 8.5 and 308 K.
[View Larger Version of this Image (17K GIF file)]


Taken together, these data allow us to propose the structure (beta -Araf-5)-P2-(1-t-myo-Ins) for the mild alkali-stable P2 phosphate and its localization at the nonreducing end of the arabinan side chains.

Substituent Structure of the Three Mild Alkali-labile P2 Phosphates

In order to determine the substituent structures of the alkali-labile P2 phosphates, the native AraLAMs were analyzed by two-dimensional NMR spectroscopy as described previously for the alkali-stable phosphates. As expected from the ratio value of P2:P1 of 4, the P1 cross-peaks in the 1H-31P HMQC-HOHAHA spectrum (Fig. 8) are weaker than those of P2. However, from P1, the myo-Ins anchor can be characterized by the proton resonances at delta  H1 4.16, delta  H2 4.35, delta  H3 3.62, delta  H4 3.66, delta  H5 3.40, and delta  H6 3.88, while the glycerol is revealed by the H-3 and H-3' (delta  4.00/3.94) proton resonances. Moreover, from the Gro H-1, H-1', and H-2 chemical shifts (3.70, 3.73, and 3.96 ppm, respectively), it can be advanced that the glycerol is not acylated (31, 32). This assignment was also supported by the absence of C-16 and C-19 methyl fatty ester in routine GC analysis of the hydrolyzed AraLAMs. From P2, this spectrum highlights the same connectivity pattern as for the one observed from P2 resonance of the dAraLAM 1H-31P HMQC-HOHAHA spectrum (Fig. 5C), indicating that P2 is linked to beta -Araf and to t-myo-Ins. The t-myo-Ins is characterized by the cross-peaks at delta  H1 3.98, delta  H2 4.28, delta  H3 3.58, delta  H4 3.67, delta  H5 3.35, delta  H6 3.77, while the beta -Araf is mainly typified by the P2 connectivity with the H-1 at 5.16 ppm. So, from these data, we propose that the three mild alkali-labile P2 phosphates present the same substituent structures as the mild alkali-stable one, (beta -Araf-5)-P2-(1-t-myo-Ins). All these phosphoinositide units cap the arabinan side chains, and by analogy to the ManLAMs, these LAMs were called phosphoinositols-glyceroarabinomannans (PI-GAMs), since the phosphatidyl anchor was found to be devoid of C-16 and C-19 fatty acids (see Fig. 10).


Fig. 8. Expanded region (delta  1H 3.10-5.30; 31P -0.58-0.10) of the 31P-decoupled, 1H-detected 63 ms HMQC-HOHAHA spectrum of AraLAMs. Numerals correspond to the proton number of the two myo-Ins units.
[View Larger Version of this Image (14K GIF file)]



Fig. 10. Partial structural model proposed for the M. smegmatis AraLAMs called PI-GAMs.
[View Larger Version of this Image (17K GIF file)]


To understand the different P2 behavior toward mild alkaline hydrolysis, the following process monitored by 31P one-dimensional NMR spectroscopy was applied to the PI-GAMs in situ in the NMR tube. The PI-GAMs were successively hydrolyzed in mild acidic (0.1 N DCl, 80 °C, 15 min) and mild alkaline (0.1 N NaOD, 40 °C, 1 h) conditions. The 31P one-dimensional spectrum (Fig. 9A) of the acidic hydrolysis subproducts is identical to that of the native PI-GAMs (Fig. 3). It is characterized by two phosphodiester resonances P1 and P2 in a ratio approximately of 1:4. P2 arises from the (Ara)n-P2-t-myo-Ins motifs (with n = 1-5), while P1 comes from the myo-Ins-P-Gro unit of the mannan core. After alkaline hydrolysis, the one-dimensional 31P spectrum (Fig. 9B) is dominated by one phosphodiester resonance assigned to P1. The ratio P2:P1 is approximately 0.2, unambiguously indicating that the P2 alkali-stable unit, observed when the PI-GAMs were treated in mild alkaline conditions, was almost completely hydrolyzed from small oligosaccharides (Ara)n-P2-t-myo-Ins. Thus, it can be advanced that the P2 alkali stability is almost no more observed when the P2 unit is contained by small oligosaccharides. Then it can be proposed that the different behavior toward mild alkaline hydrolysis of the (beta -Araf-5)-P2-(1-t-myo-Ins) motifs can be explained in terms of PI-GAM conformation (Fig. 10) that prevents the accessibility of the P2 alkali-stable unit to the alkaline reagents.


Fig. 9. 1D 31P NMR spectra (delta  31P -1.50-1.50) of M. smegmatis AraLAMs. A, after mild acidic hydrolysis (0.1 N DCl, 15 min, 80 °C); the spectrum was recorded in D2O at pH 7.6 and 313 K (ns 8704, SW 10 ppm). B, after mild alkaline hydrolysis (0.1 N NaOD, 1 h, 40 °C); the spectrum was recorded in D2O at pH 7.2 and 313 K (ns 1024, SW 10 ppm).
[View Larger Version of this Image (16K GIF file)]


Induction of TNF-alpha by Mycobacterial LAM Preparations

The potency of the PI-GAMs to stimulate the production of TNF-alpha was investigated using the human myelomonocytic cell line THP-1. Monocytes were stimulated by various preparations of LAMs at 10 µg/ml previously incubated in the presence or absence of polymyxin B (Fig. 11). PI-GAMs, like LPS, induced the THP-1 cells to release TNF-alpha (250 and 550 pg/ml, respectively). In the presence of polymyxin B, as expected, the LPS was found inactive, while the induction of TNF-alpha by PI-GAMs was not significantly abrogated. However, the mild alkaline treatment of the PI-GAMs (0.1 N NaOH, 40 °C, 2 h) decreases by a factor of 5 the production of TNF-alpha . Surprisingly, the M. smegmatis LAM fraction devoid of PI-GAMs was inactive in our bioassay even at 50 µg/ml. So, the PI-GAMs appeared to be responsible for the TNF-alpha induction by the LAM fraction of fast growing mycobacterial species (33).


Fig. 11. TNF-alpha production by human monocyte/macrophage cell line THP-1 stimulated by LPS, PI-GAMs, deacylated PI-GAMs (dPI-GAMs), or LAMs (the M. smegmatis LAMs fraction analyzed was devoid of PI-GAMs) at 10 µg/ml, preincubated in the presence (hatched bars) or absence (empty bars) of polymyxin B (10 µg/ml).
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DISCUSSION

LAMs present a large spectrum of immunological activities involving interactions with B-cells (1), phagocytes (16), and alpha beta -T lymphocytes (15). Some molecular targets of LAMs have either been identified as or suggested to be the mannose receptor (13, 14), the CD14 (12) receptor, and more recently the alpha beta T-cell receptor (15). In order to define these molecular recognition mechanisms, precise structural models must be proposed for the LAMs. Moreover, in order to determine their role in the immunopathogenesis of mycobacterial diseases, the precise knowledge of the LAM structures according to their mycobacterial origins remains a major objective. Indeed, LAMs that are ubiquitously found in the mycobacterial genus are involved in specific immunological activities according to their mycobacterial source. For example, AraLAMs from a fast growing mycobacterial species present a higher capacity to induce TNF-alpha than ManLAMs from M. tuberculosis strain Erdman (34). Still more relevant is the fact that ManLAMs from M. leprae and M. tuberculosis activate specifically different alpha beta human T-cell lines CD4- and CD8- (15).

From a structural point of view, whatever their mycobacterial origin, the LAMs share the mannan core, the phosphatidyl-myo-Ins anchor, and the arabinan domain. Furthermore, according to the structures of the arabinan side chain extremity, the LAMs were subdivided into two types, AraLAMs and ManLAMs (4). The AraLAMs, characterized by beta -D-Araf caps (8), arise from an unidentified fast growing mycobacterial species, while the ManLAMs found in the slow growing species, M. tuberculosis (4, 5). M. leprae (8) and M. bovis BCG (6, 7) are typified by manno-oligosaccharides. However, the drawback of all the structural and biological LAMs studies is the fact that LAMs are not a single molecular species, as illustrated by the broad band observed in SDS-polyacrylamide gel electrophoresis (35) and more recently by matrix-assisted laser desorption-MS (3) studies showing precisely a 6-kDa molecular mass heterogeneity.

Nevertheless, it is now clearly established that all LAM activities, whatever their structure, require the alkali-labile residues. Thus, findings concerning the structure of LAMs, in their native forms, emphasize the importance of the development of new analytical approaches. Using two-dimensional 1H-13C and 1H-31P NMR experiments, we established that the LAMs from M. smegmatis, a fast growing mycobacterial strain, belong to the AraLAM class, but more interestingly the presence, the structure, and the location of mild alkali-labile and -stable phosphoinositides were unambiguously demonstrated.

First, the fact that the M. smegmatis LAM belongs to the AraLAM class was established by one-dimensional 13C NMR and two-dimensional 1H-13C HMQC experiments. From the t-alpha -D-Manp and the 2-O-linked alpha -D-Manp anomeric carbon resonances, it was found that each of them correlated with only one anomeric proton signal instead of two in the case of the ManLAMs from M. bovis BCG (6). Thus, the M. smegmatis LAMs are composed of t-Manp and 2,6-di-O-linked Manp units restricted to the mannan core, proving that they belong to the AraLAM class. During the preparation of this paper, similar data appeared in the literature using a different analytical approach based on the FAB-MS study of LAM acetolysates (8). However, this strategy, compared with NMR analysis, requires LAM chemical degradation followed by chromatography fractioning prior to FAB-MS analysis.

Second, unexpected structural features of mild alkali-labile and alkali-stable phosphoinositides were deduced, for the first time, by direct NMR studies of the native AraLAMs. The AraLAM one-dimensional 31P spectrum unambiguously reveals the presence of two types of phosphodiester groups that resonate independently at -0.11 ppm (P1) and -0.35 ppm (P2) with an integration ratio of 1:4. Upon AraLAM treatment under mild alkaline conditions, P1 and P2 resonances are still present in the one-dimensional 31P spectrum, but their relative intensities become similar, proving the presence of three mild alkali-labile and two mild alkali-stable phosphodiester groups per molecule (Fig. 10).

The structures of the P1 and P2 substituents were directly determined from the native and the mild alkaline-treated AraLAMs by two-dimensional 1H-31P HMQC-HOHAHA experiments. Starting from the alkali-stable P1 resonance at delta  -0.11, a diester linkage with Gro and myo-Ins was established, typifying a part of the well-known phosphatidyl-myo-Ins anchor. Likewise, starting from the alkali-stable P2 resonance at -0.35 ppm, the 1H-31P HMQC-HOHAHA spectra support a phosphodiester linkage between a monosaccharide assigned to beta -D-Araf (correlation with an anomeric proton, J1,2 = 3.15 Hz) and myo-Ins. This NMR approach applied to the native AraLAM P2 resonance at -0.35 ppm reveals the same substituent structure (myo-Ins)-P2-(beta -D-Araf) for the mild alkali-labile and mild alkali-stable P2. The terminal location of the four P2-myo-Ins units was unambiguously determined from their 1H chemical shifts. Moreover, the 1H-31P HMQC experiments from the alkali-stable and -labile P2 show the same pattern characterized by three connectivities, one with the H-1 of the t-myo-Ins and the two others with the prochiral H-5 and H-5' of the beta -D-Araf, revealing that P2 binds the beta -D-Araf at C-5 and the t-myo-Ins at C-1. On the basis of these NMR data, it was proposed that the M. smegmatis AraLAMs contain two mild alkali-stable phospho-myo-Ins, one assigned to the well known phosphatidyl-myo-Ins and the other to the unexpected (t-myo-Ins-1)-P-(5-beta -D-Araf), and three alkali-labile units attributed to (t-myo-Ins-1)-P-(5-beta -D-Araf). All four (t-myo-Ins-1)-P2-(5-beta -D-Araf) units were found to cap the arabinan side chains in a process involving mild acidic AraLAM hydrolysis, P4 gel filtration, and oligosaccharide analysis by 31P NMR spectroscopy and FAB-MS.

The different behavior of the four P2 motifs, having the same substituent structures, toward mild alkaline hydrolysis was explained in terms of accessibility precluded by the AraLAM conformation. It was assumed that the three P2 alkali-labile units are exposed at the molecule surface, while the P2 alkali-stable unit must be hidden in the core of the molecule. This assumption was borne out by the fact that the P2 alkali stability almost disappeared when the P2 units were contained by small oligosaccharides (t-myo-Ins-1)-P2-(5-beta -D-Araf)-(alpha -D-Araf)n (n = 0-4) arising from AraLAM mild acidic hydrolysis.

In conclusion, the structural study of the M. smegmatis AraLAMs reveals the presence of four (t-myo-Ins-1)-P-(5-beta -D-Araf) units capping the arabinan chains, three of these units being alkali-labile. Myo-Ins-P-Araf motifs were also identified by Khoo et al. (8) using FAB-MS analysis of arabinose-containing oligosaccharides obtained either from LAM acetolysates or enzymatically from alkali-deacylated LAMs produced by an unidentified fast growing mycobacterial species. However, the structure of these motifs was incomplete (the anomeric configuration was not reported, and the sugar carbon involved in the linkage was only suggested). Moreover, on the basis of our study, it can be suggested that most of the (t-myo-Ins-1)-P-(5-beta -D-Araf) caps were lost during the LAM deacylation prior to enzymatic degradation and also during the permethylation step used to determine the proportion of phospho-myo-Ins caps. Indeed, only a minor portion (around 20%) of the arabinan side chains were found to be capped by P-myo-Ins in the case of the unidentified fast growing mycobacterial species (8). The same approach applied to the M. smegmatis LAMs suggested the absence of such caps (8). Using the same permethylation strategy (Table I), it was found that the number of terminal beta -D-Araf was equal to the number of 3,5-di-O-linked Arafs in agreement with the absence of t-beta -D-Araf caps. Nevertheless, from Table I and from the molecular weight of the mannan core,2 it can be advanced that 40-50% of the arabinan side chains are capped by P2-myo-Ins units.

In the present report, we demonstrate that three phosphoinositide motifs capping the arabinan side chains are alkali-labile groups. Moreover, from the chemical shifts of the glycerol protons and preliminary GC analysis, it was found that the AraLAMs arising from M. smegmatis cell wall solvent extraction were devoid of C-16 and C-19 fatty acids, and are therefore probably localized at the cell wall surface. This structural feature leads to two relevant conclusions: (i) the definition of a new class of related AraLAM molecules, namely PI-GAMs (for <UNL>p</UNL>hospho<UNL>i</UNL>nositols-<UNL>g</UNL>lycero<UNL>a</UNL>rabino<UNL>m</UNL>annans), which are present in the crude lipoglycan fraction obtained from M. smegmatis cell walls, and (ii) the crucial importance of the alkali-labile phosphoinositides that appear to be key structural motifs that support most of the specific immunological properties of the lipoglycans concerning the stimulation of the macrophage activation through CD14 (36), which is the major cell surface receptor for monocyte activation.

Thus, the biological activity of the PI-GAMs in eliciting TNF-alpha secretion in a human monocytic cell line was compared with that of the M. smegmatis LAMs devoid of PI-GAMs. It was clearly established that in the case of M. smegmatis strain, the AraLAM activity concerning the induction of TNF-alpha is mainly mediated by the PI-GAMs. Indeed, the AraLAM fraction devoid of PI-GAMs and characterized by the presence of C-16 and C-19 fatty acids (data not shown) was found inactive, suggesting that the fatty acid residues of the phosphatidyl myo-Ins are not involved in this process. As described previously for the AraLAMs (10), the ability of the PI-GAMs, treated in mild alkaline condition, to stimulate TNF-alpha production is drastically reduced, supporting the likelihood that alkaline groups play a major role. Our data reveal that the exposed phosphoinositides, which are alkali-labile, are of key importance and may determine the macrophage early gene response during its interaction with M. smegmatis. Thus, the ability of the PI-GAMs to trigger TNF-alpha response in promoting a potent macrophage antimicrobial activity could be the major molecular cause of the macrophage success in killing M. smegmatis cells. Therefore, the PI-GAMs seem important determinants of mycobacterial avirulence.


FOOTNOTES

*   This work was supported by grants from the Région Midi Pyrénées (RECH/9307911). The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    To whom correspondence and reprint requests should be addressed. Tel.: 33-0561335912; Fax: 33-0561335886.
1    The abbreviations used are: LAM, lipoarabinomannan; AraLAM, LAM without mannosyl extensions; dAraLAM, deacylated AraLAM; BCG, bacillus Calmette Guérin; DEPT, distortionless enhancement by polarization transfer; dLAM, deacylated LAM; GC/MS, gas chromatography/mass spectrometry; HMQC, heteronuclear multiple quantum correlation spectroscopy; HOHAHA, homonuclear Hartmann-Hahn spectroscopy; 3JH,H', vicinal spin-spin coupling constants; ManLAM, LAM with mannosyl extensions; P1 and P2, phosphates 1 and 2, respectively; PI-GAM, phosphoinositol-glyceroarabinomannan; TMS, trimethylsilylation; TNF, tumor necrosis factor; Ins, inositol; Gro, glycerol; t-, terminal; LPS, lipopolysaccharide; SW, spectral width; TPPI, time-proportional phase increment.
2    M. Gilleron, N. Himoudi, O. Adam, P. Constant, A. Venisse, M. Rivière, and G. Puzo, unpublished observation.

Acknowledgment

We gratefully acknowledge J. D. Bounéry for GC and GC/MS technical assistance.


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