LPS-dependent changes in the expression of 57 kDa and 53 kDa cell membrane proteins without participation of CD14

It is widely presumed that in addition to CD14, other molecules are necessary for lipopolysaccharide (LPS)-induced cell activation. In order to shed light on some of the biological and biochemical properties of these molecules, we examined the LPS responsiveness of CD14-negative, ST2 cells. Although ST2 cells do not express CD14 mRNA, they, nonetheless, expressed IL-6 mRNA and synthesized IL-6 protein when incubated with LPS in serum-free medium ( i.e. without soluble CD14). Paxlitacel (Taxol™) also induced IL-6 mRNA expression in ST2 cells, while Rhodobacter sphaeroides diphoshoryl lipid A (RsDPLA) inhibited both LPS- and Taxol-induced expression of IL-6 mRNA. Collectively, these data suggest that LPS, RsDPLA, and Taxol all recognize the same receptor complex on ST2 cells and do not require the participation of CD14. In addition, using antibody raised against the ST2 cell membrane fraction, we detected a set of LPS-specific membrane antigens in murine peritoneal macrophages, including two designated p57 (57 kDa) and p53 (53 kDa). There was no qualitative difference in the expression of p57 and p53 in LPS-responsive, C3H/HeN and LPS-hyporesponsive, C3H/HeJ macrophages. However, after stimulating the macrophages with LPS or Taxol, expression of p57 and p53 was diminished in C3H/HeN macrophages, but not in C3H/HeJ macrophages. Phorbol ester (PMA) and A23187 calcium ionophore did not suppress p57 or p53 expression, and the lipid A precursor, PE406, did not bind to either protein. Thus, p57 and p53 may play important roles in LPS-evoked responses, but they do not appear to serve as LPS receptors.

Lipopolysaccharide- and paclitaxel (Taxol)-induced tolerance in murine peritoneal macrophages

LPS-tolerance, a state of refractoriness to LPS-stimulation, is induced in murine peritoneal macrophages by prior exposure to LPS. LPS-induced expression of TNF and IL-6 mRNA as well as activation of various intracellular kinases and factors, including ERK, p38, JNK, Raf-1 and NF-κB were all suppressed in LPS-tolerant macrophages; responses to stimulation by paclitaxel (Taxol™), an LPS agonist, were similarly suppressed, but responses to phorbol esters (PMA) were unaffected. Binding and uptake of [125I]-labeled LPS to tolerant macrophages was somewhat greater in tolerant than in non-tolerant macrophages. Thus, the refractory state appears to involve inhibition or blockade of LPS-signaling molecules located downstream of the cell membrane LPS receptor and upstream of the branch point in the intracellular cascades leading to activation of MAPK and NFκB. LPS conditioning also suppressed LPS- and Taxol-induced TNF production, but augmented nitric oxide (NO) production. In contrast, Taxol conditioning failed to suppress LPS-induced TNF production. Conditioning with the synthetic taxoid analog, nor-seco-taxoid, which does not induce macrophage activation, enhanced LPS- and Taxol-induced NO production. These findings provide us with new information about the relationship between the LPS and Taxol receptors as well as about the signaling pathways leading to TNF and NO production.

Identification of CD18 as a novel Taxol binding/signaling protein in murine macrophage membranes

The anti-tumor agent, Taxol, is a potent LPS mimetic in murine macrophages, an activity that is dissociable from its well-characterized anti-mitotic activity which is mediated by microtubule hyperstabilization. A photoactivatable Taxol analog was used to identify components of a putative, shared LPS signaling apparatus in murine macrophage membranes. We report here that CD18, the β chain of the β2-integrin, Mac-1, represents a major Taxol binding protein in murine macrophages.

Shigella flexneri Interactions with the Basolateral Membrane Domain of Polarized Model Intestinal Epithelium: Role of Lipopolysaccharide in Cell Invasion and in Activation of the Mitogen-Activated Protein Kinase ERK

An early step governing Shigella flexneri pathogenesis is the invasion of the colonic epithelium from the basolateral surface followed by disruption of the colonic epithelial barrier. Despite recent insight into S. flexneri-host interactions, much remains to be determined regarding the nature of the initial contact between S. flexneri and the host epithelial basolateral membrane domain. Since the lipopolysaccharide (LPS) is located at the outermost part of the bacterial membrane, we considered that this component might be used by S. flexneri to attach to the basolateral surface of the intestinal epithelium and promote a proinflammatory response. Therefore, polarized human T84 intestinal epithelial cells were infected from the basolateral surface with either wild-type S. flexneri or one of its isogenic LPS-defective strains with mutations in either rfc, rfaL, or galU. We found that both adherence to and internalization into the basolateral surface of a polarized intestinal epithelium with S. flexneri were highly dependent on the length of the LPS (i.e., rfc > rfaL > galU). Furthermore, the addition of the anti-inflammatory LPS (RsDPLA) considerably decreased the invasion profile of wild-type S. flexneri by nearly 50%. Since LPS is associated with host inflammation, we further examined whether this molecule was involved in Shigella-induced inflammatory events. We found that S. flexneri LPS plays an important role in mediating epithelial-derived signaling, which leads to directed migration of polymorphonuclear leukocytes across model intestinal epithelium. This signaling most likely involves the activation of the mitogen-activated protein kinase extracellular regulated kinase. Thus, our findings have important implications on the understanding of the mechanisms by which S. flexneri can elicit mucosal inflammation.

Use of a Photoactivatable Taxol Analogue to Identify Unique Cellular Targets in Murine Macrophages: Identification of Murine CD18 as a Major Taxol-Binding Protein and a Role for Mac-1 in Taxol-Induced Gene Expression

Taxol, a potent antitumor agent that binds β-tubulin and promotes microtubule assembly, results in mitotic arrest at the G2/M phase of the cell cycle. More recently, Taxol was shown to be a potent LPS mimetic in murine, but not in human macrophages, stimulating signaling pathways and gene expression indistinguishably from LPS. Although structurally unrelated to LPS, Taxol’s LPS-mimetic activities are blocked by inactive structural analogues of LPS, indicating that despite the species-restricted effects of Taxol, LPS and Taxol share a common receptor/signaling complex that might be important in LPS-induced human diseases. To identify components of the putatively shared Taxol/LPS receptor, a novel, photoactivatable Taxol analogue was employed to identify unique Taxol-binding proteins in murine macrophage membranes. Seven major Taxol-binding proteins, ranging from ∼50 to 200 kDa, were detected. Although photoactivatable Taxol analogue failed to bind to CD14, the prominent Taxol-binding protein was identified as CD18, the ∼96-kDa common component of the β2 integrin family. This finding was supported by the concomitant failure of macrophage membranes from Mac-1 knockout mice to express immunoreactive CD18 and the major Taxol-binding protein. In addition, Taxol-induced IL-12 p40 mRNA was markedly reduced in Mac-1 knockout macrophages and anti-Mac-1 Ab blocked secretion of IL-12 p70 in Taxol- and LPS-stimulated macrophages. Since CD18 has been described as a participant in LPS-induced binding and signal transduction, these data support the hypothesis that the interaction of murine CD18 with Taxol is involved in its proinflammatory activity.

Lipopolysaccharide (LPS) stimulates the production of tumor necrosis factor (TNF)-alpha and expression of inducible nitric oxide synthase (iNOS) by osteoclasts (OCL) in murine bone marrow cell culture

Osteoclasts (OCL) resorb bone. They are essential for the development of normal bones and the repair of impaired bones. The function of OCL is presumed to be supported by cytokines and other biological mediators, including tumor necrosis factor (TNF)-alpha and nitric oxide (NO). Bacterial lipopolysaccharide (LPS) is a potent inducer of TNF-alpha and inducible nitric oxide synthase (iNOS), which is the specific enzyme for synthesizing NO from L-arginine. To obtain direct evidence on LPS-induced TNF-alpha production and iNOS expression by OCL, OCL-enriched cultures were prepared by 7-day cocultures of bone marrow cells of adult BALB/c mice and osteoblastic cells (OBs) derived from calvaria of newborn BALB/c mice, and the generation of TNF-alpha and iNOS in OCL stimulated with LPS was examined immunocytochemically. When the cultured cells were stimulated with 100 ng/ml of LPS, OCL clearly showed TNF-alpha and iNOS expression. Without LPS-stimulation, no expression was observed. TNF activity in the culture supernatants of the OCL-enriched cultures in the presence of LPS was also detected by cytotoxic assay that used TNF-sensitive L929 cells. The dentin resorption activity of OCL was estimated by area and number of pits formed on dentin slices, which were covered by the OCL fraction and cultured in the presence or absence of LPS, sodium nitroprusside (SNP; a NO generating compound), N(G)-monomethyl L-arginine acetate (L-NMMA; a competitive inhibitor of NO synthase (NOS)), or LPS plus L-NMMA. Pit formation was obviously inhibited in the presence of SNP and slightly inhibited in the presence of L-NMMA, but it was not affected in the presence of LPS or LPS plus L-NMMA. These findings indicate that OCL produces TNF and expresses iNOS in response to LPS, but the LPS-activation of OCL scarcely affects pit formation by them.

Participation of CD14 in the phagocytosis of smooth-type Salmonella typhimurium by the macrophage-like cell line, J774.1

The role of CD14 in the phagocytosis and killing of microorganisms was investigated using macrophage-like cell lines, CD14-positive J774.1 cells and CD14-negative mutant J7.DEF.3 cells derived from J744.1 cells. The cells were infected with Salmonella typhimurium organisms of the smooth (S)-form LT2, mutant rough (R)-form TV148 or Staphylococcus aureus 248betaH. At 30 or 180 min incubation, the cells were washed and disrupted. Colony-forming units (CFUs) liberated from the disrupted cells were determined by quantitative cultivation, and the phagocytic index and killing rate were calculated. Both the phagocytic index and killing rate of J774.1 cells against LT2 organisms were greater than those of J7.DEF.3 cells. However, the index and rate of J774.1 cells against TV148 and 248betaH organisms were similar to those of the J7.DEF.3 cells. The phagocytosis of LT2 organisms by J774.1 cells was partially inhibited by S-form LPS (S-LPS) and anti-CD14 antibody, but not by R-chemotype LPS (R-LPS). These results suggest that CD14 participates in the phagocytosis of S-form Salmonella.