Interferon-gamma and interleukin-4 down-regulate soluble CD14 release in human monocytes and macrophages.

CD14 is a 53-kd glycoprotein that is mainly expressed in myeloid cells and exists in two forms. The membrane-bound form represents the receptor for complexes of lipopolysaccharide (LPS) with LPS binding protein. The function and regulation of the soluble form are unknown. In the present study we investigated the release of soluble CD14 (sCD14) in cultures of human mononuclear leukocytes, elutriated monocytes, and monocyte-derived macrophages. The release of sCD14 into the medium of the cells cultured for 15 and 45 h was investigated in the absence or presence of selected cytokines. sCD14 release occurred constitutively and correlated with cell number. In monocytes differentiating into macrophages, cumulative release of sCD14 was linear from day 1 to day 7. Spontaneous sCD14 release after 15 h of culture (2 x 10(6) cells/ml) was higher in the supernatant from monocytes (314 +/- 58 ng/ml) than that from mononuclear leukocytes (68 +/- 10 ng/ml) and similar to that from macrophages (469 +/- 79 ng/ml). Cycloheximide and actinomycin D inhibited sCD14 release. Recombinant interferon-gamma (rIFN-gamma) and recombinant interleukin-4 (rIL-4) directly decreased sCD14 release in mononuclear leukocyte, monocyte, and macrophage cultures. rIL-2 and rIFN-alpha reduced sCD14 release into the supernatants of mononuclear leukocytes only. Use of anti-IFN-gamma antibodies indicated that the down-regulation of sCD14 release by rIL-2 and rIFN-alpha was partially due to induction of endogenous IFN-gamma. The down-regulation of sCD14 release by all four cytokines was both time and dose dependent. rIFN-gamma and rIL-4 added simultaneously had a synergistic effect on sCD14 down-regulation. In conclusion, sCD14 release may have an immunomodulatory role in circulating monocytes, is apparently not related to the process of macrophage differentiation, and is selectively down-regulated during an immune response when levels of IFN-gamma and IL-4 are high.     

Helicobacter pylori and Porphyromonas gingivalis lipopolysaccharides are poorly transferred to recombinant soluble CD14.

Helicobacter pylori and Porphyromonas gingivalis are gram-negative bacteria associated with chronic inflammatory diseases. These bacteria possess lipopolysaccharides (LPSs) that are able to activate human monocytes to produce tumor necrosis factor alpha but fail to activate human endothelial cells to express E-selectin. With Escherichia coli LPS, tumor necrosis factor alpha activation requires membrane-bound CD14 and E-selectin expression requires soluble CD14 (sCD14). Therefore, the ability of H. pylori and P. gingivalis LPSs to transfer to and bind sCD14 was examined by using immobilized recombinant sCD14 and human serum or recombinant LPS-binding protein (LBP). H. pylori and P. gingivalis LPSs were transferred to sCD14 when serum or LBP was present. However, the transfer of these LPSs to CD14 in serum was significantly slower than the transfer of E. coli LPS. Quantitation of the transfer rates by Michaelis-Menten kinetics yielded K(m) values of 6 and 0.1 nM for H. pylori and E. coli LPSs, respectively. The amount of P. gingivalis LPS required to obtain half-maximum binding to CD14 was approximately 10-fold greater than the amount of E. coli LPS required. The slower transfer rates displayed by these LPSs can be explained by the poor binding to LBP observed in direct binding assays. These results are consistent with the proportionately lower ability of these LPSs to activate monocytes compared with E. coli LPS. However, the ability of H. pylori and P. gingivalis LPSs to bind LBP and transfer to sCD14 demonstrates that the lack of endothelial cell CD14-dependent cell activation by these LPSs occurs distal to sCD14 binding.     

Human lactoferrin interacts with soluble CD14 and inhibits expression of endothelial adhesion molecules, E-selectin and ICAM-1, induced by the CD14-lipopolysaccharide complex

Lipopolysaccharides (LPS), either in the free form or complexed to CD14, a LPS receptor, are elicitors of the immune system. Lactoferrin (Lf), a LPS-chelating glycoprotein, protects animals against septic shock. Since optimal protection requires administration of Lf prior to lethal doses of LPS, we hypothesized that interactions between Lf and soluble CD14 (sCD14) exist. In a first step, human sCD14 and human Lf (hLf) were used to determine the kinetic binding parameters of hLf to free sCD14 in an optical biosensor. The results demonstrated that hLf bound specifically and with a high affinity (K(d) = 16+/-7 nM) to sCD14. Affinity chromatography studies showed that hLf interacted not only with free sCD14 but also, though with different binding properties, with sCD14 complexed to LPS or lipid A-2-keto-3-deoxyoctonic acid-heptose. In a second step, we have investigated whether the capacity of hLf to interact with sCD14 could modulate the expression of endothelial-leukocyte adhesion molecule 1 (E-selectin) or intercellular adhesion molecule 1 (ICAM-1) induced by the sCD14-LPS complex on human umbilical vein endothelial cells (HUVEC). Our experiments show that hLf significantly inhibited both E-selectin and ICAM-1 expressions at the surface of HUVEC. In conclusion, these observations suggest that the anti-inflammatory effects of hLf are due not only to the ability of the molecule to chelate LPS but also to its ability to interact with sCD14 and with the sCD14 complexed to LPS, thus modifying the activation of endothelial cells.     

Endotoxin-neutralizing capacity of soluble CD14.

Luminol-enhanced chemiluminescence was used to determine the effect of soluble CD14 (sCD14) on the endotoxin-inducible generation of reactive oxygen species in human monocytes. It was necessary to mediate lipopolysaccharide (LPS) monocyte-activating capability by serum factors (LPS-binding proteins). sCD14 reduced LPS-inducible monocyte activation in a dose-dependent manner, even in the case of CD14- monocytes, obtained from a patient with paroxysmal nocturnal haemoglobinuria. These monocytes could be activated by opsonized LPS via other receptors. Using anti-mouse Ig-coated microbeads, it was demonstrated in FACS analysis that sCD14 mediates the binding of a mouse monoclonal anti-CD14 antibody (RoMo 1) to a complex of LPS/FITC (fluoroisothiocyanate) and a LPS-binding protein. The release of sCD14 from cultured monocytes was measured using LPS, TNF alpha (tumour necrosis factor), IL1, 4 and 6 (interleukin-1, -4 and -6) and IFN gamma (interferon-gamma) as stimulators. Addition of LPS and TNF alpha led to a dose-dependent increase in sCD14-levels in the culture supernatant, whereas IL1, IL6 and IFN gamma had no significant effect. IL4 dose-dependently depressed spontaneous sCD14 release. It is possible that elevated sCD14-serum levels in polytraumatized patients indicate a natural protective mechanism against excessive monocyte mediator production. Therefore, sCD14 may be a new therapeutic concept in endotoxic shock prevention.     

Synthesis and surface expression of CD14 by human endothelial cells

Previous studies have reported that human vascular endothelial cells lack the membrane-bound lipopolysaccharide (LPS) receptor, CD14 (mCD14). By optimizing assay conditions, including the selection of anti-CD14 monoclonal antibody, we now demonstrate that human umbilical vein endothelial cells (HUVEC) express CD14 on the cell surface. Single-passage HUVEC showed approximately 20 times less expression of CD14 than monocytes. Interestingly, there was significant loss of surface CD14 expression with increasing numbers of culture passages. Evidence for synthesis of CD14 by HUVEC was provided by the finding that L-[(35)S]methionine was incorporated into CD14. In addition, the expression of CD14 on HUVEC was upregulated by LPS, lysophosphatidic acid, and tissue culture supplements, and this upregulation was dependent on protein synthesis. Furthermore, the results imply that mCD14 is required for LPS-induced activation of endothelial cells in the absence of serum and that it acts in concert with serum factors (soluble CD14). Our results provide evidence that CD14 is expressed by endothelial cells and suggest that the previous inability to observe expression of this molecule has been due to culture and staining conditions. This finding has important implications for the understanding of the mechanisms by which LPS stimulates endothelial cells and the management of sepsis caused by gram-negative bacteria.     

Monocyte CD14: a multifunctional receptor engaged in apoptosis from both sides.

Like all other immune system cells, monocytes and macrophages may undergo apoptotic cell death in response to specific triggers and mediators or as a consequence of aging. However, factors inducing apoptosis and the involved cellular and molecular mechanisms are much better investigated and understood for lymphocytes. Th2 cell-derived cytokines such as interleukin-4 (IL-4) are able to induce monocyte apoptosis most effectively. This process is preceded by down-regulation of the CD14 surface receptor. Mediators such as lipopolysaccharide (LPS) suppress and postpone apoptosis in parallel with up-regulation of CD14. Macrophages are rather resistant against apoptotic damage, and factors able to evoke apoptosis in monocytes are often ineffective in macrophages. Resistance of macrophages against apoptotic triggers may be beneficial for inflammatory processes where macrophages are engaged and needed as phagocytes for ingestion and removal of moribund cells. The multifunctional CD14 receptor of monocytes/macrophages is supposed to be involved in the apoptotic network on both sides: as a surface molecule of monocytes that can promote survival and antagonize apoptosis and as a recognition receptor of macrophages that enables or supports interaction with apoptotic cells.     

Soluble lipopolysaccharide receptor (CD14) is released via two different mechanisms from human monocytes and CD14 transfectants

The receptor for lipopolysaccharide LPS (CD14) exists in a membrane-associated (mCD14) and a soluble form (sCD14). Previous studies indicate that monocytes produce sCD14 by limited proteolysis of the membrane-bound receptor. In this study we demonstrate that human monocytes also produce sCD14 by a protease-independent mechanism. To investigate the molecular nature of this second pathway we studied sCD14 formation in the monocytic cell line Mono Mac 6 (MM6) and in CD14 transfectants. Both MM6 and the CD14 transfectants constitutively produce sCD14 by a protease-independent mechanism. Structural analysis of sCD14 produced by the CD14 transfectants reconfirmed the presence of the COOH terminus predicted from the cDNA. Since glycosylphosphatidyl-inositol anchor attachment is associated with the removal of a hydrophobic C-terminal signal peptide, our finding demonstrates that the transfectants secrete sCD14 which escaped this posttranslational modification. Identical results obtained for sCD14 derived from peritoneal dialysis fluid of a patient with kidney dysfunction show the in vivo relevance of this pathway for sCD14 production.     

Lipopolysaccharide complexed with soluble CD14 binds to normal human monocytes

Using flow cytometry we have compared the binding of Neisseria meningitidis lipopolysaccharide labeled with fluorescein isothiocyanate (FITC-LPS) to normal human monocytes in whole blood with the binding to Chinese hamster ovary (CHO) cells transfected with human CD14 gene (hCD14-CHO cells). Binding of FITC-LPS to cells was dose dependent, saturable and enhanced in the presence of increasing concentrations of serum. Blockade of membrane CD14 with saturating concentrations of anti-CD14 monoclonal antibody (mAb) My4 inhibited 50% of the binding of FITC-LPS to monocytes and 100% to hCD14-CHO cells. Similarly, removal of membrane CD14 by phosphatidylinositol phospholipase C (Pl-PLC) treatment of the cells partially decreased the binding of FITC-LPS to monocytes but totally inhibited the binding to hCD14-CHO-transfected cells. These results suggest that binding of FITC-LPS to monocytes is not only mediated by membrane CD14. Using two-color flow cytometry, we observed that FITC-LPS binds to My4-saturated monocytes in association with soluble (s)CD14 present in serum as revealed by staining with rhodaminelabeled My4 mAb. The binding of FITC-LPS/sCD14 complexes to monocytes treated with saturating amounts of unlabeled My4 prior to addition of the complexes was completely inhibited by anti-CD14 mAb 10G33. When cells were first saturated with a mixture of My4 and 10G33 mAb, washed and further incubated with FITC-LPS/sCD14, inhibition of the binding of LPS was similar to that observed with cells saturated with My4 alone, showing that the binding of FITC-LPS is not mediated by the 10G33 epitope present on mCD14. These results suggest that either the 10G33 epitope on sCD14 is involved in the binding of LPS/sCD14 complexes to the cells, or that 10G33 mAb inhibits the binding of FITC-LPS to sCD14. Taken together, these data indicate that sCD14 which is present in normal serum, in addition to membrane CD14, enables LPS to bind monocytes through an as yet unidentified molecule and that sCD14 does not simply serve as a shuttle for transfer of LPS to membrane CD14.     

Both membrane-bound and soluble forms of CD14 bind to Gram-negative bacteria

Tissue macrophages and their precursors – the blood monocytes – respond rapidly to a bacterial infection with the release of inflammatory mediators. These mediators are involved in the recruitment of phagocytic cells, principally neutrophils, from the blood to the site of infection. To initiate this process macrophages and monocytes must be able to detect the presence of bacteria in a reliable, but nevertheless nonspecific, fashion. It is thought that this is achieved by means of receptors on the cell surface which recognize structures common to many different bacteria. One candidate for such a “pattern recognition element” is the cell surface glycoprotein CD 14. CD 14 has been shown to bind components of the Gram-positive cell wall and it also binds soluble lipopolysaccharide released from Gram-negative bacteria. In both cases the interaction with CD 14 leads to an activation of the cell. Here we show that human peripheral blood monocytes can, in addition, bind intact Gram-negative bacteria in the presence of serum and that this process involves CD14. When CD14 expression is induced on the myelomonocytic cell line U937 by treatment with vitamin D3 the cells concomittently acquire the capacity to bind bacteria. Furthermore, a non-monocytic cell line which does not bind bacteria acquires the capacity to do so when transfected with either the human or mouse CD14 gene. This binding can be inhibited by blocking the CD14 receptor with anti-CD14 antibody or by blocking the ligand on the bacteria with soluble CD14. Finally we demonstrate binding of sCD14 to Escherichia coli. We conclude that in the presence of serum both membrane-bound and soluble forms of CD14 can bind to Gram-negative bacteria. This suggests that CD14 may play a role in the detection and elimination of intact bacteria in vivo.     

Increased Levels of Soluble CD14 in Sera of Periodontitis Patients

Soluble CD14 (sCD14) mediates the response to lipopolysaccharide (LPS) in cells lacking membrane-bound CD14. We determined sCD14 concentrations in the sera of 38 periodontitis patients and 25 healthy controls by enzyme-linked immunosorbent assay. The sCD14 levels in the sera of patients with periodontitis were significantly higher than those of healthy subjects and decreased after treatment. Enhanced levels of sCD14 in serum may contribute to the host response to LPS in periodontitis. Furthermore, we showed in vitro that addition of LPS enhanced the release of sCD14 by monoblastic U937 cells treated with 1α,25-dihydroxyvitamin D₃. Thus, increased sCD14 levels in periodontitis patients may be due to chronic exposure to LPS.     

Serum CD14 levels in polytraumatized and severely burned patients.

Recently it has been demonstrated that the CD14 molecule which is expressed on monocytes and macrophages serves as a receptor for lipopolysaccharide (LPS) bound to LPS-binding protein (LBP) and thus mediates LPS-induced tumour necrosis factor (TNF) production. Here we report that CD14 is found as a soluble (s) molecule in serum. In healthy volunteers sCD14 levels (mean +/- s.e.m.) were 3.7 +/- 0.05 micrograms/ml (n = 30, 25-50 years of age) as determined by ELISA (detection limit 20 ng/ml serum) using two monoclonal antibodies in a sandwich technique. In polytraumatized patients (n = 16) significantly decreased levels (1.7 +/- 0.3) were detected immediately after the trauma, which increased to 4.9 +/- 0.3 micrograms/ml within the first 6 days post trauma. sCD14 remained elevated during the first 14 days post trauma in patients with the most severe injuries (injury severity score greater than 45 points), whereas a return to normal levels was observed in patients with an injury score of less than 45 points. In addition, the levels of the high-density lipoproteins that partially inactivate free endotoxin are significantly decreased post trauma. No correlation between parameters of inflammation (C3a and neopterin levels, leucocyte counts, amount of band cells), liver function and sCD14 levels was established. Comparable to polytraumatized patients, increased sCD14 serum levels were observed in five patients with burn trauma (burned area greater than 35%) within the second week post trauma when clinical signs of septicaemia were evident.     

Recombinant CD36 inhibits oxLDL-induced ICAM-1-dependent monocyte adhesion

A key event in atherosclerosis is the interaction between monocytes and endothelial cells. Binding of oxidized low-density lipoprotein (oxLDL) to CD36 on endothelial cells results in activation and subsequent monocyte adhesion. In this study, a recombinant soluble CD36 molecule was expressed to delineate its ability to block the adhesion of monocytes. To construct soluble CD36, the extra-cellular domain of CD36 was fused to the Fc domain of human IgG1. The N-terminal sequence of CD36 was replaced with N-terminal signal peptide sequence of CD59, a type I membrane protein. The resulting chimeric sCD36-Ig cDNA (sCD36-Ig) was transfected into COS-7 and CHOK1 cells and supernatants were analyzed for secretion of this molecule. Sandwich ELISA and oxLDL binding analyses showed that recombinant sCD36-Ig is secreted in a functionally active form. Western blot analysis of the purified sCD36-Ig using three different anti-CD36 monoclonal antibodies and anti-human IgG showed that the chimeric sCD36-Ig is a dimer of 220kDa. Further, the sCD36-Ig inhibited the adhesion of monocytes to oxLDL. Interestingly, sCD36-Ig blocked the oxLDL-induced adhesion of monocytes to the endothelial cell specific protein, ICAM-1. Our results indicate that the chimeric sCD36-Ig protein is folded correctly and can effectively compete for the binding of oxLDL to membrane-expressed CD36. These results suggest that oxLDL-induced monocyte adhesion can be blocked using sCD36-Ig and this may be useful in blocking the cell-cell interaction leading to atherogenesis.     

Urinary soluble CD14 mediates human proximal tubular epithelial cell injury induced by LPS

Renal proximal tubular epithelial cells (PTEC) are target for LPS during sepsis and renal infections. In the present study, we evaluated whether stimulation of human PTEC by LPS is modulated through the soluble or the membrane form of the LPS receptor CD14. We found that PTEC lacked expression of the membrane form of CD14 and did not release soluble CD14 (sCD14). sCD14 was detected in the urine of normal subjects and it was increased in patients with renal sepsis or with proteinuria. In the presence of sCD14 and LPS binding protein (LBP), PTEC were 10 to 100-fold more sensitive to LPS activation, resulting in cytokine production (IL-6, IL-8 and TNF-alpha) and NO release. We found that sCD14 purified from urine was biologically active on PTEC. Moreover, the presence of sCD14 and LBP was required for cytotoxicity induced by low concentrations of LPS (1-10 ng/ml) in PTEC. Cell death showed the characteristics of both necrosis and apoptosis, as demonstrated by LDH release and by TUNEL and acridine orange staining and caspase-3 activation. Whereas the LPS alone was sufficient to induce necrosis, sCD14 and LBP were required for apoptosis. Our results suggest that sCD14 excreted in urine may participate with endotoxin in the activation and injury of renal proximal tubules. In particular, sCD14 may contribute to the tubulo-interstitial injury in clinical settings characterised by proteinuria and enhanced susceptibility to infections such as in diabetes.     

Interactions of bacterial lipopolysaccharide and peptidoglycan with a 70 kDa and an 80 kDa protein on the cell surface of CD14+ and CD14- cells

Bacterial cell wall components, lipopolysaccharide (LPS), lipoteichoic acid (LTA), and peptidoglycan (PGN) are known to stimulate cells of the immune, inflammatory and vascular systems contributing to septic shock. CD14 has been identified as the main LPS receptor, a process that is accelerated by the serum protein LPS-binding protein (LBP). CD14 has also been found to bind LTA and PGN from the cell wall of gram positive bacteria. Recently, toll-like receptor proteins TLR-2 and TLR-4 have been shown to be required for LPS and LTA-induced intracellular signalling. Although CD14 functions as either a glycosylphosphatidylinositol (GPI)-anchored molecule that does not transverse the cell membrane or as a soluble serum protein, the mechanisms by which the CD14-LPS/LTA complex interacts with the TLRs remains to be elucidated. We have looked directly for cell surface protein(s) that bind LPS or LTA in a CD14-dependent manner. Using biochemical approaches we have identified two proteins of molecular weight 70 kDa (LAP-1) and 80 kDa (LAP-2) that can be precipitated from both CD14(+) and CD14(-) cells with LPS- or LTA-specific antibodies. Binding of LPS and LTA to LAP-1 and -2 required serum. While soluble CD14 (sCD14) was sufficient to allow precipitation of these two proteins from CD14(-) cells, serum could not be replaced by purified sCD14 and/or LBP when mCD14-expressing cells were used.     

Effect of CD14 promoter polymorphism and H. pylori infection and its clinical outcomes on circulating CD14

CD14 is a pattern recognition receptor on the membranes of monocytes and macrophages for several microbial products, of which lipopolysaccharide (LPS) is the best known. A shed form of CD14 is present in serum. As the CD14 gene promoter polymorphism -159C/T and some bacterial infections may affect the sCD14 levels, we compared the impact of both the CD14 promoter polymorphism and Helicobacter pylori infection on serum sCD14 levels in 201 dyspeptic patients (group 1) who had undergone gastroscopy, and 127 staff members (group 2) with no endoscopy. sCD14 was measured from the sera by a commercial enzyme immunoassay (EIA), and CD14 genotyping was carried out with PCR. Helicobacter pylori infection was detected by serology and/or culture or PCR. sCD14 levels were elevated in the subjects carrying the T allele (CT or TT genotype) in both groups when compared with subjects with the CC genotype. Overall, H. pylori-positive subjects tended to have higher sCD14 levels compared with H. pylori-negative subjects. In group 1 consisting of dyspeptic patients, those with gastric ulcer, gastric erosion or duodenal ulcer had significantly elevated levels of sCD14 compared with the patients with normal endoscopic findings or macroscopic gastritis. The recent use of NSAIDs was also associated with enhanced sCD14. Thus, we were able to show several factors, one genetic and the other environmental (H. pylori infection and mucosal lesion), to have an impact on sCD14.     

Membrane CD14, but not soluble CD14, is used by exoenzyme S from P. aeruginosa to signal proinflammatory cytokine production

Recognition of TLR agonists involves a complex interplay among a variety of serum and cell membrane molecules, including mCD14 and sCD14 that is not fully understood. TLR activation results in downstream signaling that induces inflammatory cytokine production in response to pathogenic molecules, such as ExoS, which is a TLR2 and TLR4 agonist produced by the opportunistic pathogen Pseudomonas aeruginosa. We reasoned that responses to ExoS, a protein, might differ from canonical TLR agonists such as LPS. Stimulating the expression of mCD14 with vitamin D3 enhanced the response to ExoS and LPS. Also, blocking anti-CD14 antibody or removing mCD14 using PLC reduced responses to ExoS and LPS. Furthermore, CD14-deficient cells were unable to bind and respond to ExoS, which was restored by stable transfection of mCD14, indicating that mCD14 was required for the response to ExoS. However, addition of sCD14 to culture enhanced responsiveness to LPS but not ExoS. Moreover, the addition of serum did not alter the response to ExoS but enhanced the response to LPS. Despite differences of adaptor molecule use between ExoS and LPS, lipid antagonists that compete for LPS binding to CD14 also inhibited the response to ExoS. These results highlight a fundamental difference between TLR agonists in their requirements for CD14 and serum components. These results suggest that understanding the dissimilarities and targeting overlapping sites of interaction on CD14 may yield a synergistic, clinical benefit during infections where a variety of TLR agonists are present.     

Evaluation of soluble CD14 and neopterin as serum parameters of the inflammatory activity of pulmonary sarcoidosis

Summary CD14 represents the most specific marker for monocytes/macrophages. It has been demonstrated in vitro that monocytes/macrophages lose this antigen upon activation. Results of studies investigating the expression of membrane-bound CD14 on the surface of monocytes/macrophages in sarcoidosis patients are controversial. To investigate whether the soluble form of CD14 reflects monocyte/macrophage activation in sarcoidosis, serum levels of soluble CD14 were determined concurrently with other serum markers of monocyte/macrophage activation (neopterin, angiotensin-converting enzyme) in 50 consecutive patients with bioptically confirmed sarcoidosis. The patients were allocated to three groups according to disease activity and therapy. The soluble interleukin-2 receptor in serum and the CD4/CD8 ratio in lavage fluid were used to monitor T-lymphocyte activation. No significant differences in serum or bronchoalveolar lavage levels of soluble CD14 were observed in patients with active or inactive sarcoidosis. Despite the presence of normal soluble CD14 serum concentrations a correlation with serum neopterin and angiotensin-converting enzyme was found in active sarcoidosis (soluble CD14 versus neopterin, r _s = 0.61 and 0.65, P< 0.05 and 0.01, respectively; soluble CD14 versus angiotensin-converting enzyme, r_s=0.6 and 0.72, P< 0.02 and 0.003, respectively). A correlation between soluble CD14 and parameters of T-cell activity was not demonstrated. We therefore conclude that soluble CD14 in serum is not a useful clinical parameter in establishing disease activity in sarcoidosis. Neopterin and angiotensin-converting enzyme serum concentrations are parameters with higher sensitivity, although specificity remains very low. The exact role of CD14 antigen in sarcoidosis requires further investigation.Abbreviations BAL bronchoalveolar lavage - BALF bronchoalveolar lavage fluid - ELISA enzyme-linked immunosorbent assay - sIL-2R soluble interleukin-2 receptor - ACE angiotensin converting enzyme - sCD14 soluble cluster of differentiation 14 Supported by the Naturwissenschaftlich-Medizinisches Forschungszentrum, Mainz, and the Federal Ministry of Technology and Research, FRG (no. 01KE8804/0)     

Soluble CD14 Activates Monocytic Cells Independently of Lipopolysaccharide

The glycoprotein CD14 acts as a receptor for lipopolysaccharide (LPS), either when anchored in the myeloid cell membrane (mCD14) or as a soluble molecule (sCD14) in serum. sCD14-LPS complexes activate cells devoid of mCD14. However, the role of sCD14 independent of LPS is unknown. Therefore, the effect of sCD14 on monocyte functions was investigated in the monocytic cell lines THP1 and Mono Mac 6 and in fresh human monocytes. Under serum-free conditions, endotoxin-free human recombinant sCD14_1–348 (rsCD14_1–348) induced tumor necrosis factor alpha (TNF-α). The TNF-α effect was stronger in THP1 cells than in Mono Mac 6 cells or monocytes. It was dose dependent, with a maximum at 1 μg/ml, and time dependent, with a maximum after 2 h. sCD14 purified from urine had the same cytokine-activating capacity. In contrast, C-terminally truncated rsCD14_1–152 was inactive. The rsCD14 effect was not due to LPS contamination, since it was resistant to polymyxin and lipid IVa but sensitive to heat and trypsin. The rsCD14-induced cytokine induction was blocked by preincubation of rsCD14 with a monoclonal anti-CD14 antibody that did not recognize the LPS-binding site. Release of the TNF-α disappeared upon pretreatment of rsCD14 in 50% plasma or in complete, heat-inactivated or sCD14-depleted serum. Moreover, cytokine production was no longer observed when rsCD14 was pretreated with thrombocytes. The thrombocyte effect was dose and time dependent. In conclusion, sCD14 is able to activate myeloid cells, and the effect is prevented by the presence of plasma, serum, or thrombocytes.