Time-dependent distinct roles of Toll-like receptor 4 in a house dust mite-induced asthma mouse model.

House dust mites (HDMs) are a common source of allergens that trigger both allergen-specific and innate immune responses in humans. Here, we examined the effect of allergen concentration and the involvement of Toll-like receptor 4 (TLR4) in the process of sensitization to house dust mite allergens in an HDM extract-induced asthma mouse model.　Intranasal administration of HDM extract induced an immunoglobulin E response and eosinophilic inflammation in a dose-dependent manner from 2.5 to 30 µg/dose. In TLR4-knockout mice, the infiltration of eosinophils and neutrophils into the lung was decreased compared with that in wild-type mice in the early phase of inflammation (total of three doses). However, in the late phase of inflammation (total of seven doses), eosinophil infiltration was significantly greater in TLR4-knockout mice than in wild-type mice. This suggests that the roles of TLR4 signaling are different between the early phase and the later phase of HDM allergen-induced inflammation. Thus, innate immune response through TLR4 regulated the response to HDM allergens, and the regulation was altered during the phase of inflammation.

Migration of lactic acid, lactide and oligomers from polylactide food-contact materials.

Polylactide (PLA) is used for manufacturing lunch boxes and for packaging fresh food in Japan. PLA can be hydrolysed relatively easily to produce lactic acid, lactide and oligomers. Different types of PLA sheet were subjected to migration tests under various conditions and the lactic acid, lactide and oligomers contents of the migration solutions were determined using liquid chromatography/mass spectrometry (LC/MS). Furthermore, the change in molecular weight was determined by a migration test. PLA was stable at 40 degrees C for 180 days; the total of lactic acid, lactide and oligomers migration levels were 0.28-15.00 microg cm(-2). PLA decomposed clearly at 60 degrees C for only 10 days, the total migration levels were increased to 0.73-2840 microg cm(-2). PLA sheets with a high D-lactic acid content decomposed particularly rapidly. The amounts of alkali decomposition products, based on the conversion of lactide and oligomers to lactic acid by alkali hydrolysis, corresponded with the total migration levels.

Biological properties of the native and synthetic lipid A of Porphyromonas gingivalis lipopolysaccharide.

INTRODUCTION AND METHODS: A pentaacyl and diphosphoryl lipid A molecule found in the lipid A isolated from Porphyromonas gingivalis lipopolysaccharide (LPS) was chemically synthesized, and its characteristics were evaluated to reconfirm its interesting bioactivities including low endotoxicity and activity against LPS-unresponsive C3H/HeJ mouse cells. RESULTS: The synthesized P. gingivalis lipid A (synthetic Pg-LA) exhibited strong activities almost equivalent to those of Escherichia coli-type synthetic lipid A (compound 506) in all assays on LPS-responsive mice, and cells. LPS and native lipid A of P. gingivalis displayed overall endotoxic activities, but its potency was reduced in comparison to the synthetic analogs. In the assays using C3H/HeJ mouse cells, the LPS and native lipid A significantly stimulated splenocytes to cause mitosis, and peritoneal macrophages to induce tumor necrosis factor-alpha and interleukin-6 production. However, synthetic Pg-LA and compound 506 showed no activity on the LPS-unresponsive cells. Inhibition assays using some inhibitors including anti-human Toll-like receptor 2 (TLR2) and TLR4/MD-2 complex monoclonal antibodies showed that the biological activity of synthetic Pg-LA was mediated only through the TLR4 signaling pathway, which might act as a receptor for LPS, whereas TLR2, possibly together with CD14, was associated with the signaling cascade for LPS and native lipid A of P. gingivalis, in addition to the TLR4 pathway. CONCLUSION: These results suggested that the moderated and reduced biological activity of P. gingivalis LPS and native lipid A, including their activity on C3H/HeJ mouse cells via the TLR2-mediated pathway, may be mediated by bioactive contaminants or low acylated molecules present in the native preparations having multiple lipid A moieties.

Migration of formaldehyde and acetaldehyde into mineral water in polyethylene terephthalate (PET) bottles.

The levels of formaldehyde (FA) and acetaldehyde (AA) in polyethylene terephthalate (PET) bottles and in commercial mineral water are reported. All the water samples bottled in Japan contained detectable levels of FA (10.1-27.9 microg l(-1)) and AA (44.3-107.8 microg l(-1)). Of 11 European bottled water samples, eight did not contain either FA or AA, while the remaining three had detectable levels of FA (7.4-13.7 microg l(-1)) and AA (35.9-46.9 microg l(-1)). In three North American bottled water samples, two contained FA (13.6 and 19.5 microg l(-1)) and AA (41.4 and 44.8 microg l(-1)), and one did not. Regardless of the region of origin, all the sterilized water samples contained FA and AA, whilst in contrast, none of the unsterilized water without carbonate contained FA or AA. Of the carbonated water samples, three contained FA and AA, and one did not. When fortified with FA and AA, the commercial water sample without otherwise detectable FA and AA was able to reduce levels, although the commercial water sample containing FA and AA could not. The presence of bacteria in the commercial water samples was investigated using an ATP-based bioluminescent assay and heterotrophic plate count method. The commercial water without FA and AA contained heterotrophic bacteria, whilst the commercial water with FA and AA did not contain detectable bacteria. It is suggested that in this case both FA and AA migrated from PET materials, but were subsequently decomposed by the heterotrophic bacteria in the unsterilized water.

Survey of formaldehyde, acetaldehyde and oligomers in polyethylene terephthalate food-packaging materials.

Polyethylene terephthalate (PET) is frequently used as a packaging material for beverage bottles, fruit and vegetable trays, and egg crates in Japan. Levels of formaldehyde (FA), acetaldehyde (AA) and PET oligomers in various PET food packaging were determined. PET samples were initially dissolved in trifluoroacetic acid with 2,4-dinitrophenylhydrazine to derivatize formaldehyde and acetaldehyde to their dinitrophenylhydrazones. The stable derivatives along with the oligomers were analysed using HPLC with ultraviolet light detection at 360 and 254 nm, respectively. The PET pellets contained 3.5-12.4 microg g-1 AA and 4.0-7.2 mg g-1 oligomers, while FA was below the determination limit. FA, AA and oligomer levels in Japanese bottles were 0.6-3.0 microg g-1, 8.4-25.7 microg g-1 and 5.0-8.7 mg g-1, ND-1.6 microg g-1, 5.0-13.1 microg g-1 and 4.9-8.2 mg g-1 in French and Italian bottles, and ND-1.2 microg g-1, 9.1-18.7 microg g-1 and 5.6-8.0 mg g-1 in US and Canadian bottles, respectively. Compared with European bottles, Japanese bottles contain higher FA and AA levels. In sheet-moulding products, their contents were determined as ND-1.1 microg g-1, 11.5-43.1 microg g-1 and 4.6-9.2 mg g-1, respectively. The results show that sheet-moulding products contain lower FA and higher AA in comparison with bottles. FA and AA are considered to be generated from PET during the heating process for moulding the pellets to bottles or sheet-moulding articles and de-aeration during the sheet-moulding process is effective in removing FA. In contrast, the level of the oligomers remains unchanged during the moulding process from pellets to bottles or sheet products.

Structure determination of minor red pigment in carthamus red colorant isolated by preparative LC/MS.

Carthamin is a well-known major pigment in carthamus red colourant. When analysed by HPLC on an ODS column, the colorant separated into two distinct reddish pigments, with both components having almost identical photodiode array spectra. LC/MS analysis suggested one of the compounds was carthamin, whilst the other was an unknown minor pigment. The minor pigment was purified and isolated from the colorant by preparative LC/MS collecting the faction based on monitoring the deprotonated molecule [M-H](-) m/z 953 in electrospray negative-ion mode. The structure was elucidated as a hydroxyethyl ether of carthamin, a novel compound, by means of NMR and HR-FAB-MS analyses.

N-linked glycosylations at Asn(26) and Asn(114) of human MD-2 are required for toll-like receptor 4-mediated activation of NF-kappaB by lipopolysaccharide.

MD-2 is physically associated with Toll-like receptor 4 (TLR4) and is required for TLR4-mediated LPS signaling. Western blotting analysis revealed the presence of three forms of human (h)MD-2 with different electrophoretic mobilities. After N-glycosidase treatment of the cellular extract prepared from cells expressing hMD-2, only a single form with the fastest mobility was detected. Mutation of either one of two potential glycosylation sites (Asn(26) and Asn(114)) of MD-2 resulted in the disappearance of the slowest mobility form, and only the fastest form was detected in hMD-2 carrying mutations at both Asn(26) and Asn(114). Although these mutants were expressed on the cell surface and maintained its ability to associate with human TLR4, these mutations or tunicamycin treatment substantially impaired the ability of MD-2 to complement TLR4-mediated activation of NF-kappaB by LPS. LPS binding to cells expressing CD14, TLR4, and MD-2 was unaffected by these mutations. These observations demonstrate that hMD-2 undergoes N-linked glycosylation at Asn(26) and Asn(114), and that these glycosylations are crucial for TLR4-mediated signal transduction of LPS.

Biological properties of lipid A isolated from Flavobacterium meningosepticum.

The biological properties of the lipid A from Flavobacterium meningosepticum, which we recently isolated and whose complete chemical structure has been determined (H. Kato, T. Iida, Y. Haishima, A. Tanaka, and K. Tanamoto. J. Bacteriol. 180:3891--3899, 1998), were studied. The lipid A exhibited generally moderate activity compared to Salmonella enterica subsp. enterica serovar abortus equi lipopolysaccharide (LPS) used as a control in the assay systems tested; lethal toxicity in galactosamine-sensitized mice, mitogenicity in mouse spleen cells, induction of tumor necrosis factor alpha (TNF-alpha) release from mouse peritoneal macrophages and J774-1 mouse macrophage-like and human THP-1 line cells, nitric oxide induction activity from J774-1 cells, and Limulus gelation activity. The moderate activity of the F. meningosepticum lipid A may be explained by its unique fatty acid composition and the lack of a phosphate group in position 4'. It is noteworthy that the lipid A apparently induced TNF-alpha release from peritoneal macrophages in LPS-unresponsive C3H/HeJ mice and that the activation was suppressed by the LPS-specific antagonist, succinylated lipid A precursor. Significant splenocyte mitogenicity in C3H/HeJ mice was also observed with the lipid A. Taken together with the previous results concerning Porphyromonas gingivalis lipid A, which has a high level of structural similarity to the lipid A of F. meningosepticum, and the induction of TNF-alpha release in macrophages from C3H/HeJ mice, the lipid A of F. meningosepticum, which has novel fatty acids, may possibly play an role for the activation of C3H/HeJ macrophages.

Salmonella-type heptaacylated lipid A is inactive and acts as an antagonist of lipopolysaccharide action on human line cells.

The stimulation of both THP-1 and U937 human-derived cells by Salmonella lipid A preparations from various strains, as assessed by TNF-alpha induction and NF-kappaB activation, was found to be very low (almost inactive) compared with Escherichia coli lipid A, but all of the lipid As exerted strong activity on mouse cells and on Limulus gelation activity. Experiments using chemically synthesized E. coli-type hexaacylated lipid A (506) and Salmonella-type heptaacylated lipid A (516) yielded clearer results. Both lipid A preparations strongly induced TNF-alpha release and activated NF-kappaB in mouse peritoneal macrophages and mouse macrophage-like cell line J774-1 and induced Limulus gelation activity, although the activity of the latter was slightly weaker than that of the former. However, 516 was completely inactive on both THP-1 and U937 cells in terms of both induction of TNF-alpha and NF-kappaB activation, whereas 506 displayed strong activity on both cells, the same as natural E. coli LPS. In contrast to the action of the lipid A preparations, all the Salmonella LPSs also exhibited full activity on human cells. However, the polysaccharide portion of the LPS neither exhibited TNF-alpha induction activity on the cells when administered alone or together with lipid A nor inhibited the activity of the LPS. These results suggest that the mechanism of activation by LPS or the recognition of lipid A structure by human and mouse cells may differ. In addition, both 516 and lipid A from Salmonella were found to antagonize the 506 and E. coli LPS action that induced TNF-alpha release and NF-kappaB activation in THP-1 cells.

Induction of lethal shock and tolerance by Porphyromonas gingivalis lipopolysaccharide in D-galactosamine-sensitized C3H/HeJ mice.

Lipopolysaccharide (LPS) obtained from Porphyromonas gingivalis was found to exhibit marked lethal toxicity in galactosamine-sensitized C3H/HeJ mice. Although no lethality was observed in mice intraperitoneally challenged with 1 mg of P. gingivalis LPS without galactosamine, when they were sensitized with 30 mg of galactosamine, challenge with 1 and 10 micrograms of LPS resulted in 67 and 100% lethality, respectively. The lethal dose of LPS was almost the same in LPS-responsive C57BL/6 mice and non-LPS-responsive C3H/HeJ mice. Furthermore, when 1 microgram of P. gingivalis LPS was administered to each mouse 90 min before the challenge with the same LPS with galactosamine, tolerance to the lethal action of LPS was induced, and the mice were completely protected from death, even at a dose 100-fold greater than the lethal dose of LPS. Neither a lethal effect nor induction of tolerance to the lethality of P. gingivalis LPS was exhibited by Salmonella LPS in galactosamine-sensitized C3H/HeJ mice. A protein-LPS complex derived from Pseudomonas aeruginosa, which exhibited strong lethality and induced tolerance to a subsequent challenge with a lethal dose of LPS in galactosamine-sensitized LPS-responsive mice, did not exhibit lethal toxicity in galactosamine-sensitized C3H/HeJ mice and failed to induce tolerance in these mice to the lethality of P. gingivalis LPS. These results indicate that P. gingivalis LPS plays the central role in the activation of non-LPS-responsive C3H/HeJ mice.

Chemical structure of lipid A isolated from Flavobacterium meningosepticum lipopolysaccharide.

The chemical structure of the lipid A of the lipopolysaccharide component isolated from Flavobacterium meningosepticum IFO 12535 was elucidated. Methylation and nuclear magnetic resonance analyses showed that two kinds of hydrophilic backbone exist in the free lipid A: a beta (1-->6)-linked 2-amino-2-deoxy-D-glucose, which is usually present in enterobacterial lipid A's, and a 2-amino-6-O-(2, 3-diamino-2,3-dideoxy-beta-D-glucopyranosyl)-2-deoxy-D-glucose, in a molar ratio of 1.00:0.35. Both backbones were alpha-glycosidically phosphorylated in position 1, and the hydroxyl groups at positions 4, 4', and 6' were unsubstituted. Liquid secondary ion-mass spectrometry revealed a pseudomolecular ion at m/z 1673 [M-H]- as a major monophosphoryl lipid A component carrying five acyl groups. Fatty acid analysis showed that the lipid A contained 1 mol each of amide-linked (R)-3-OH iC17:0, ester-linked (R)-3-OH iC15:0, amide-linked (R)-3-O-(iC15:0)-iC17:0, and both amide- and ester-linked (R)-3-OH C16:0. Fatty acid distribution analyses using several mass spectrometry determinations demonstrated that the former two constituents were distributed on positions 2 and 3 of the reducing terminal unit of the backbones and that the latter two were attached to the 2' and 3' positions in the nonreducing terminal residue.

A novel inhibitor of bacterial endotoxin derived from cinnamon bark.

A substance that inhibits the activity of bacterial endotoxin (LPS) was found in cinnamon bark. The inhibitor, extracted from dry cinnamon bark with 67% ethanol/water, was purified by using Limulus gelation activity as an indicator of endotoxin activity. The inhibitor suppressed the activity of the LPS when it was mixed with the inhibitor prior to the assay. The reduction of the LPS activity depended on the concentration of both the inhibitor and LPS when mixed, and also on the incubation time. The inhibitor suppressed the activity of all LPS and lipid A preparations tested regardless of the origin of the bacteria. The inhibitor alone did not affect the Limulus system. These results indicate that the inhibition was caused by direct interaction of the inhibitor with the LPS molecule. Furthermore the inhibitor abrogated the pyrogenicity of the LPS. Although it is uncertain whether the inhibitor actually plays a role in the defense mechanism in cinnamon bark, this is the first report that an inhibitor of bacterial endotoxin exists in a plant.

The lipid A moiety of Porphyromonas gingivalis lipopolysaccharide specifically mediates the activation of C3H/HeJ mice.

The lipid A preparation isolated from Porphyromonas gingivalis was found to induce splenocyte mitogenicity and TNF-alpha release from peritoneal macrophages in LPS-unresponsive C3H/HeJ mice to the same extent as in LPS-responsive mice. In order to clarify whether the activation of C3H/HeJ mice was specifically caused by the lipid A and not by contaminating protein, two strategies were employed. The lipid A fraction from P. gingivalis was subjected to either hydrochloric acid or alkaline treatment to eliminate either glycosylated phosphate or O-acylated fatty acids from the lipid A structure, and the biologic activities of the derivatives were compared in both LPS-responsive and unresponsive C3H/HeJ mice. De-1-O-phosphorylated P. gingivalis lipid A showed partial loss, and de-O-acylated lipid A complete loss of splenocyte mitogenic and TNF-alpha-inductive activities from peritoneal macrophages in both LPS-responsive and unresponsive mice. The relative activities of the intact and treated lipid A compounds in splenocyte mitogenicity and TNF-alpha-inductive activity in macrophages were similar to the relative activities of these preparations in Limulus gelation activities. The LPS-specific antagonist, succinylated lipid A precursor, inhibited P. gingivalis lipid A-mediated splenocyte mitogenicity and TNF-alpha induction in macrophages in a similar manner in LPS-responsive and unresponsive mice. These results strongly suggest that the activation of LPS-unresponsive C3H/HeJ mice by P. gingivalis lipid A was specifically mediated by the lipid A portion and not by contaminating protein. The characteristic action of P. gingivalis lipid A on LPS-unresponsive C3H/HeJ mice was thought to reflect the unique chemical properties of this compound.

Chemical structure of lipid A isolated from Comamonas testosteroni lipopolysaccharide.

The chemical structure of lipid A of lipopolysaccharide isolated from Comamonas testosteroni was determined by quantitative analysis, methylation analysis, mass spectrometry and NMR spectroscopy. The lipid A backbone was found to consist of 6-O-(2-deoxy-2-amino-beta-D-glucopyranosyl)-2-deoxy-2-amino-alpha-D-g luc ose which was phosphorylated in positions 1 and 4'. Hydroxyl groups at positions 4 and 6' were unsubstituted, and position 6' of the non-reducing terminal residue was identified as the attachment site of the polysaccharide part. Liquid secondary-ion/mass spectrometry revealed a pseudomolecular ion at m/z 1572 [M-H]- as a major diphosphoryl lipid component carrying six acyl groups. Fatty acid distribution analysis and electrospray ionization/mass spectrometry of the lipid A showed that positions 2,2',3, and 3' of the sugar backbone were N-acylated or O-acylated by (R)-3-hydroxydecanoic acid, and that the hydroxyl groups of the amide-linked residues attached to positions 2 and 2' were further O-acylated by tetradecanoic and dodecanoic acids, respectively.

Chemically detoxified lipid A precursor derivatives antagonize the TNF-alpha-inducing action of LPS in both murine macrophages and a human macrophage cell line.

The chemically synthesized disaccharide precursor of lipid A (406) has been demonstrated to reduce its activity in mice by an order of 10(5) or more by replacing the hydroxyl groups with succinyl or acetyl residues. In the present study, these chemically detoxified synthetic lipid A precursors were found to antagonize the LPS action of inducing TNF-alpha in both murine peritoneal macrophages and in human monocyte-macrophage cell line THP-1. These preparations were found to antagonize the induction of TNF-alpha in murine macrophages by both stimulants of LPS and untreated 406, which acts as an agonist in the murine system, in a dose-dependent manner. Complete inhibition by succinylated 406 occurred at 10-fold excesses of the antagonist. Succinylated precursor also antagonized the TNF-alpha-inducing action of LPS in human cell line THP-1. The precursor itself also exhibited antagonism in this assay. The activity of the succinylated 406, however, was much more potent than that of the unmodified precursor. These derivatives do not inhibit either the Limulus gelation activity of LPS, or the induction of TNF-alpha in macrophages by zymosan, indicating that the inhibition is not caused by molecular interaction and that the inhibition is specific to LPS action. These findings suggest common features in murine macrophage and human monocytic cell receptors. They also suggest the importance of the substituents on the hydroxyl groups of 3-hydroxy fatty acids of the nonreducing glucosamine of lipid A for the activity and for transformation to the antagonistic structure.

Structural study on the free lipid A isolated from lipopolysaccharide of Porphyromonas gingivalis.

The chemical structure of lipid A isolated from Porphyromonas gingivalis lipopolysaccharide was elucidated by compositional analysis, mass spectrometry, and nuclear magnetic resonance spectroscopy. The hydrophilic backbone of free lipid A was found to consisted of beta(1,6)-linked D-glucosamine disaccharide 1-phosphate. (R)-3-Hydroxy-15-methylhexadecanoic acid and (R)-3-hydroxyhexadecanoic acid are attached at positions 2 and 3 of the reducing terminal residue, respectively, and positions 2' and 3' of the nonreducing terminal unit are acylated with (R)-3-O-(hexadecanoyl)-15-methylhexadecanoic acid and (R)-3-hydroxy-13-methyltetradecanoic acid, respectively. The hydroxyl group at position 4' is partially replaced by another phosphate group, and the hydroxyl groups at positions 4 and 6' are unsubstituted. Considerable heterogeneity in the fatty acid chain length and the degree of acylation and phosphorylation was detected by liquid secondary ion-mass spectrometry (LSI-MS). A significant pseudomolecular ion of lipid A at m/z 1,769.6 [M-H]- corresponding to a diphosphorylated GlcN backbone bearing five acyl groups described above was detected in the negative mode of LSI-MS. Predominant ions, however, were observed at m/z 1,434.9 [M-H]- and m/z 1,449.0 [M-H]-, each representing monophosphoryl lipid A lacking (R)-3-hydroxyhexadecanoic and (R)-3-hydroxy-13-methyltetradecanoic acids, respectively. The presence of mono- and diphosphorylated lipid A species was also confirmed by LSI-MS of de-O-acylated lipid A (m/z 955.3 and 1,035.2, respectively).

Dissociation of endotoxic activities in a chemically synthesized lipid A precursor after acetylation.

In a previous study, a chemically synthesized disaccharide precursor of lipid A (406; identical to lipid IVA) was shown to have dramatically reduced lethality, B-cell mitogenicity, and tumor necrosis factor induction in macrophages when its hydroxyl groups were replaced with either succinyl or acetyl residues (K. Tanamoto, FEBS Lett. 351:325-329, 1994). Succinylated 406 was found to lose Limulus amoebocyte lysate gelation activity completely as a result of the modification (about 10(5)-fold), too, as expected. However, acetyl 406, surprisingly, exhibited activity comparable to that of the original 406. Both succinylated and acetylated 406 lost pyrogenicity completely. These results indicate that one of the typical endotoxic activities was dissociated from the others and that the ability to induce Limulus amoebocyte lysate gelation is not always representative of endotoxin activity.

Predominant role of the substituents on the hydroxyl groups of 3-hydroxy fatty acids of non-reducing glucosamine in lipid A for the endotoxic and antagonistic activity.

The synthetic disaccharide precursor of lipid A (406: identical to lipid IVA) was found to reduce its endotoxic activity in mice by an order of 10(5) or more, by replacing the hydroxyl groups with succinyl or acetyl residues. Both the succinylated and acetylated 406 were also found to antagonize the endotoxic mitogenicity on murine splenocytes. Previous studies demonstrated that the succinylated or acetylated synthetic complete lipid A preparations retained the whole endotoxic activity [1994, Infect. Immunol. 62, 1705]. The drastic contrast in all of these results suggests the importance of the substituents on the hydroxyl groups of 3-hydroxy fatty acids of non-reducing glucosamine of lipid A for the activity and for transformation to the antagonistic structure.

Free hydroxyl groups are not required for endotoxic activity of lipid A.

Previous studies demonstrated that lipid A from Salmonella abortusequi loses its B-cell mitogenicity for murine spleen cells as a result of the introduction of succinyl residues on hydroxyl groups and that the inactivated lipid A specifically antagonizes the mitogenicity of endotoxin. Hypothesizing that the hydroxyl groups are essential both for its biological activity and for producing nontoxic preparations having antagonistic activity, I tested the role of the hydroxyl groups in its activities by using well-characterized biologically active lipid A preparations synthesized chemically (Escherichia coli and Salmonella types 506 and 516, respectively) by the introduction of either succinyl or acetyl residues at the hydroxyl groups of each of these lipid A preparations. However, the biological activities of neither lipid A preparation were reduced at all after succinylation; in fact, succinylated 516 became much more potent than the original molecule with respect to most activities tested, i.e., lethal toxicity, Limulus gelation activity, and the induction of tumor necrosis factor release. On the other hand, when the hydroxyl groups were replaced with acetyl residues, the lethality and tumor necrosis factor-inducing activity of both lipid A preparations were decreased, whereas their Limulus gelation activity was increased. Mitogenicity was not affected much by the chemical modifications of either lipid A preparation. These findings indicate that although the residues introduced into the free hydroxyl groups of lipid A modulate its activities, the hydroxyl groups in lipid A need not exist in free form.