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Regulation of Endotoxin-Induced Proinflammatory Activation in Human Coronary Artery Cells: Expression of Functional Membrane-Bound CD14 by Human Coronary Artery Smooth Muscle Cells¹

Lynn L. Stoll^2,*, Gerene M. Denning, Wei-Gen Li^*, James B. Rice^*, Allan L. Harrelson^*, Sara A. Romig^*, Skuli T. Gunnlaugsson^*, Francis J. Miller, Jr^* and Neal L. Weintraub^*

Divisions of ^* Cardiovascular Diseases and Infectious Diseases, Department of Internal Medicine, University of Iowa, Iowa City, IA 52242

	Abstract

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Low-level endotoxemia has been identified as a powerful risk factor for atherosclerosis. However, little is known about the mechanisms that regulate endotoxin responsiveness in vascular cells. We conducted experiments to compare the relative responses of human coronary artery endothelial cells (HCAEC) and smooth muscle cells (HCASMC) to very low levels of endotoxin, and to elucidate the mechanisms that regulate endotoxin responsiveness in vascular cells. Endotoxin (1 ng/ml) caused production of chemotactic cytokines in HCAEC. Endotoxin-induced cytokine production was maximal at LPS-binding protein:soluble CD14 ratios <1, typically observed in individuals with subclinical infection; higher LPS-binding protein:soluble CD14 ratios were inhibitory. Endotoxin potently activated HCASMC, with cytokine release >10-fold higher in magnitude at >10-fold lower threshold concentrations (10–30 pg/ml) compared with HCAEC. This remarkable sensitivity of HCASMC to very low endotoxin concentrations, comparable to that found in circulating monocytes, was not due to differential expression of TLR4, which was detected in HCAEC, HCASMC, and intact coronary arteries. Surprisingly, membrane-bound CD14 was detected in seven different lines of HCASMC, conferring responsiveness to endotoxin and to lipoteichoic acid, a product of Gram-positive bacteria, in these cells. These results suggest that the low levels of endotoxin associated with increased risk for atherosclerosis are sufficient to produce inflammatory responses in coronary artery cells. Because CD14 recognizes a diverse array of inflammatory mediators and functions as a pattern recognition molecule in inflammatory cells, expression of membrane-bound CD14 in HCASMC implies a potentially broader role for these cells in transducing innate immune responses in the vasculature.

	Introduction

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Atherosclerosis is increasingly recognized as a chronic inflammatory disorder (1, 2, 3), but the sources of vascular inflammation remain to be elucidated. One potentially important source of vascular inflammation is endotoxin (LPS), a unique glycolipid contained in the outer leaflet of the outer wall of Gram-negative bacteria (4, 5). Gram-negative organisms colonize the human gastrointestinal, genitourinary, and respiratory tracts, and generate endotoxin not only during overt infections, but also in subclinical conditions (e.g., periodontitis) that are common in patients with atherosclerotic disease (6).

Endotoxin can be detected in the plasma of apparently healthy individuals who are free of clinical infection. Epidemiological studies indicate that endotoxemia at levels as low as 50 pg/ml represents a strong risk factor for the development of atherosclerosis (7, 8). A variety of Gram-negative infections were associated with an increased risk of atherosclerosis (8), supporting the hypothesis that endotoxin may be pathogenically linked to the development of atherosclerosis.

Although endotoxin has been shown to evoke proinflammatory responses in cultured vascular cells (9), most prior studies were conducted in bovine aortic endothelial cells (EC)³ or HUVECs using very high (µg/ml) concentrations of endotoxin. Concentrations of endotoxin in this range are even higher than those observed in sepsis and may activate host cells by mechanisms independent of the CD14/TLR4-signaling pathway (10, 11, 12, 13). Also, very few studies have examined endotoxin responses in coronary artery cells, despite that fact that this vascular bed exhibits enhanced susceptibility to atherosclerosis in many patients. Thus, prior studies offer little insight into how low-level endotoxemia might contribute to atherosclerosis.

We have recently shown that human blood vessel explants are extremely sensitive to very low (picograms per milliliter) levels of endotoxin (14). The responses to endotoxin in intact blood vessels were far more potent than have been reported in cultured human EC. Because most of the vessel wall is composed of smooth muscle cells (SMC), these findings suggested to us that vascular SMC might be highly responsive to endotoxin, and, therefore, might play a previously unappreciated role in transducing immune responses in the vascular wall. Therefore, we initiated a series of experiments to compare the relative responses of human coronary artery (HCA)EC and HCASMC to very low levels of endotoxin, and to elucidate the mechanisms that regulate endotoxin responsiveness in vascular cells. In these studies, we examined the expression of membrane-bound CD14 (mCD14) and TLR4 in HCA cells. In addition, we investigated the modulatory effects of LPS-binding protein (LBP) and soluble CD14 (sCD14) on vascular cell activation by endotoxin. Our findings provide important insights into the mechanisms by which circulating endotoxin could contribute to atherosclerosis in humans, and by which vascular SMC may contribute importantly to innate immunity in the vasculature.

	Materials and Methods

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Cell culture

HCAEC and HCASMC were isolated from coronary arteries obtained at the time of heart transplantation at the University of Iowa using previously described methods (15, 16). Some HCAEC and HCASMC were purchased from Clonetics (San Diego, CA) and Cell Applications (San Diego, CA) and were maintained in the supplier’s medium. All cells were subcultured at a 1:3 ratio or less, and were used for experiments from passages 7 to 9. Chinese hamster ovary (CHO) cells stably transfected with human CD14 (CHO/CD14) or the vector pKoNeo (CHO/Neo) were a generous gift of Dr. D. Golenbock (17). To maintain selective pressure, CHO/CD14 and CHO/Neo cells were maintained in M199 with 5% FBS with 10 µg/ml ciprofloxacin and 400 µg/ml G418; however, both ciprofloxacin and G418 were withdrawn from cells plated for experiments. Preprepared medium and FBS used in these studies contained <3 pg/ml and <7 pg/ml endotoxin, respectively.

Cell viability assays

Cell viability was assessed by 3-(4,5-dimethalthiazol-2-yl)-5-(3-carboxymethyloxphenyl)-2-(4-sulfenyl)-2H-tetrazolium, inner salt (MTS) assay using a test kit (Promega, Madison, WI) according to the manufacturer’s instructions (18).

IL-8 and MCP-1 ELISAs

Cytokines were measured by ELISA, using matched Abs from R&D Systems (Minneapolis, MN), as described previously (19).

Assays for TLR4 and CD14 expression

Expression of TLR4 in HCAEC and HCASMC was analyzed by RT-PCR, Western blot analysis, and immunohistochemistry, as described previously (14). Expression of CD14 (394 bp) in HCAEC, HCASMC, and U937 cells (as a positive control) was analyzed by RT-PCR, as described for TLR4 (14). The oligonucleotide primers used were: 5'-ACTTATCGACCATGGAGC and 5'-AGGCATGGTGCCGGTTA.

Determination of mCD14 surface expression on cultured cells

Cells were grown to confluence in 48-well plates; assays were performed on cells in their original plates. Each well was gently rinsed twice, then incubated for 1 h at 37°C with mouse anti-human CD14 mAb (MEM-18; Accurate, Westbury, NY) or UCH-M1 or SCA-1 (Santa Cruz Biotechnology, Santa Cruz, CA) at a dilution range from 1/8,000 to 1/512,000. For each well treated with primary Ab, there was a control well treated with buffer lacking primary Ab. The primary Ab was then removed; the plates were washed three times and then incubated 1 h at 37°C with biotinylated anti-mouse IgG (A85-1; BD Pharmingen, San Diego, CA) at a 1/2000 dilution. Plates were washed three times and then incubated with HRP-streptavidin (Pierce, Rockford, IL; 1/2000) for 30 min at 37°C. The plates were then rinsed again and incubated with 200 µl of TMB solution (Sigma-Aldrich, St. Louis, MO) for 5 min. The color reaction was halted with the addition of 0.5 M H₂SO₄. The contents of each well were then transferred to a 96-well plate and read at 450 nm on a Thermomax microplate reader (Molecular Devices, Sunnyvale, CA). Data for each experiment were averaged from triplicate wells exposed to primary Ab, and corrected for background by subtracting the average absorbance values from the control wells lacking primary Ab.

Treatment of HCASMC with phosphoinositide-specific phospholipase C (PLC-)

HCASMC monolayers were preincubated for 2 h with 0.2 U/ml PLC- (Sigma-Aldrich) in serum-free M-199 with 0.1% human serum albumin (HSA). Control HCASMC were preincubated with vehicle alone. Following this preincubation, the HCASMC were washed twice with HBSS containing 1 µM HSA to remove the cleaved CD14, along with other GPI-anchored proteins. The cells were then incubated for 24 h with 3 ng/ml LPS + 100 ng/ml LBP, and the medium was assayed for IL-8 release as previously described. To exclude the possibility of nonspecific cell damage, exogenous sCD14 (250 ng/ml) was added to some groups of cells.

Other reagents

LPS from Escherichia coli K12 LCD25 was purchased from List Biological Laboratories (Campbell, CA) and purified by phenol reextraction (20). Human recombinant LBP and sCD14 were a generous gift from Amgen (Thousand Oaks, CA). All other reagents, including lipoteichoic acid (LTA) from Streptococcus pyogenes, were purchased from Sigma-Aldrich.

Statistical analysis

Results are expressed as mean ± SEM. The data were analyzed by ANOVA followed by Bonferroni t testing.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
In initial studies, we compared responses to clinically relevant concentrations of endotoxin on HCAEC and HCASMC. Experiments were routinely performed using E. coli K12 LCD25 endotoxin. Some experiments were also performed with Neisseria meningitidis endotoxin and E. coli K12 lipid A, with qualitatively similar results (data not shown).

Endotoxin is not directly cytotoxic to HCAEC or HCASMC at concentrations up to 10 ng/ml

Endotoxin has been reported to cause direct toxic effects and increased permeability in EC. In our model system, LPS at concentrations up to 10 ng/ml produced no cytotoxicity in HCAEC or HCASMC, as measured by a standard assay of cell viability (data not shown). Further, when HCAEC were grown as polarized monolayers on micropore filters, 10 ng/ml endotoxin caused no changes in electrical resistance of the monolayer through at least 6 h (data not shown).

Effects of low levels of endotoxin on IL-8 and MCP-1 release by HCAEC and HCASMC

Fig. 1 shows the effect of endotoxin on release of IL-8 and MCP-1, two important proinflammatory cytokines that are known to play a crucial role in recruitment of monocytes, neutrophils, and T lymphocytes to atherosclerotic lesions. Fig. 1A shows that endotoxin produced potent dose-dependent increases in release of IL-8 and MCP-1 from HCAEC. Increases in cytokines were observed only after >4 h incubation with endotoxin, consistent with a transcriptional mechanism of induction, rather than release of preformed protein. As compared with similar studies in HUVEC, the HCAEC exhibited greater endotoxin responsiveness in regard to both the magnitude of IL-8 release (typically 6–8 ng/well, compared with 2–3 ng/well for HUVEC) and the fold increase over baseline (average 4-fold for HUVEC, 7-fold for HCAEC; data not shown).

View larger version (18K): [in this window] [in a new window]   FIGURE 1. LPS causes release of proinflammatory cytokines in HCA cells. A, LPS-induced IL-8 and MCP-1 release by HCAEC: concentration dependence. HCAEC were grown to confluence in 48-well plates. Cells were incubated for 24 h in MEM with 2% FBS and increasing concentrations (0.1–10 ng/ml) of LPS. Media were then collected and analyzed by ELISA for IL-8 (solid line) and MCP-1 (broken line). Data represent mean ± SEM of media from four individual wells for each condition in one of five experiments with similar results. *, p = < 0.05 vs 0 LPS. B, LPS-induced IL-8 and MCP-1 release by HCASMC: concentration dependence. HCASMC monolayers in 48-well plates were incubated for 24 h with MEM containing 2% FBS and increasing concentrations (0.01–1 ng/ml) of LPS. Data represent mean ± SEM of media collected from four individual wells for each condition in one of four experiments with similar results. *, p = < 0.05 vs 0 LPS.

TLR4 expression by HCAEC and HCASMC

TLR4 has been proposed as a critical transmembrane component of the endotoxin receptor complex in a number of cell types, including human dermal microvascular EC (21). Because of the striking difference in LPS responsiveness of HCASMC compared with HCAEC, we looked for possible differential expression of TLR4 in coronary artery cells. Fig. 2 shows the expression of TLR4 in both HCAEC and HCASMC, as detected by both RT-PCR (A) and Western blot analysis (B). Similar findings were obtained by both RT-PCR and Western blot analysis for TLR2 (data not shown). Fig. 2C shows the results of immunohistochemical analysis of a frozen section of a HCA stained for TLR4. The brown staining is consistent with strong TLR4 expression in the coronary endothelium and in the medial smooth muscle. TLR4 staining in the neointima of this atherosclerotic vessel appeared to be considerably reduced as compared with the endothelial and medial layers. Although none of these techniques is strictly quantitative, all three are consistent in suggesting that TLR4 is expressed by HCAEC at least as strongly as in HCASMC. Thus, these findings suggest that differential expression of TLR4 is unlikely to account for differences in endotoxin responsiveness between HCAEC and HCASMC.

View larger version (50K): [in this window] [in a new window]   FIGURE 2. HCAEC and HCASMC express TLR4. A, Expression of TLR4 (548 bp) in HCAEC and HCASMC was analyzed by RT-PCR. GAPDH (452 bp) was used as an internal control. B, Western blot analysis of TLR4 protein, using rabbit anti-human TLR4 Ab (Santa Cruz Biotechnology). C, Immunostaining of HCA for TLR4. Left panel, negative control with secondary Ab only; right panel, inclusion of primary and secondary Abs. E, endothelium; N, neointima; M, media. For details, see Ref. 14 .

In addition to TLR4, CD14 is involved in endotoxin signaling in inflammatory cells. The level of mCD14 can be an important determinant of endotoxin-induced cellular activation (10). Further, a CD14 promoter polymorphism has been linked to increased risk of myocardial infarction in individuals with otherwise low coronary risk (22). Considering the potent endotoxin responsiveness of HCASMC, we asked whether HCASMC might express mCD14. As shown in Fig. 3A, mRNA for CD14 was highly expressed in HCASMC, at a level similar to that detected in U-937 cells.

View larger version (21K): [in this window] [in a new window]   FIGURE 3. HCASMC, but not HCAEC, express mCD14. A, RT-PCR analysis of mCD14 expression. Expression of CD14 (394 bp) in U-937, HCAEC, and HCASMC was analyzed by RT-PCR. Total RNA was isolated as previously described (14 ), and PCR amplification was performed as described (14 ). B, CHO cells stably transfected with a CD14 expression plasmid show specific CD14 cell surface protein expression. CHO/CD14 cells and control CHO cells transfected with the empty vector (CHO/Neo) were grown to confluence in 48-well plates. Cells were incubated for 1 h at 37°C with the anti-CD14 mAb UCH-M1 at dilutions from 1/8,000 to 1/512,000, as described under Materials and Methods. Cells were then incubated with biotinylated anti-mouse IgG (1/2000) for 1 h, followed by streptavidin treatment and color development, as described in Materials and Methods. Absorbance was read at 450 nm; values for each well were corrected for control (absence of primary Ab). Data points are averages of triplicate determinations from duplicate wells from one of three experiments with similar results. Similar results were obtained with MEM-18 and SCA-1. *, p = < 0.05 vs CHO/Neo controls. C, CD14 cell surface immunoreactivity is present on cultured HCASMC, but not HCAEC. HCAEC and HCASMC grown in 48-well plates were treated as described above with primary Ab (MEM-18, dilutions ranging from 1/512,000 to 1/8,000), followed by biotinylated secondary Ab, HRP-streptavidin, and TMB solution. Results are shown as mean ± SEM of corrected absorbance values from triplicate wells at each Ab concentration in one of three individual experiments with similar results. *, p = < 0.05 vs HCAEC.

We then asked whether the mCD14 detected by the cell surface ELISA was functionally active in the HCASMC. We incubated HCAEC and HCASMC with increasing concentrations of LPS (0–10 ng/ml) in serum-free medium (SFM) containing albumin and LBP ± sCD14. Although expression of low levels of mRNA for mCD14 was detected in HCAEC (Fig. 3A), LPS failed to consistently induce significant IL-8 release from HCAEC in the absence of exogenous sCD14 (Fig. 4A). However, IL-8 release from HCASMC was similar with or without added sCD14 (Fig. 4B). Similar sCD14-independent responses were observed in six other lines of passaged HCASMC (two lines purchased from commercial suppliers and four isolated in our laboratory) (data not shown).

View larger version (18K): [in this window] [in a new window]   FIGURE 4. HCASMC, but not HCAEC, express functional mCD14 that transduces LPS signaling. A, Dependence of LPS-induced IL-8 release by HCAEC on sCD14. Confluent HCAEC monolayers in 48-well plates were incubated for 24 h in serum-free MEM containing 0.1% HSA, 100 ng/ml LBP ± 250 ng/ml sCD14, and increasing concentrations (0–10 ng/ml) of LPS. Media were then collected and analyzed by ELISA for IL-8. Data represent mean ± SEM of media from four individual wells for each condition in one of four experiments with similar results. *, p = < 0.01 vs LBP alone. B, Role of sCD14 in LPS-induced IL-8 release by HCASMC. Confluent HCASMC monolayers in 48-well plates were incubated as described for HCAEC. Before addition of LPS, some wells were pretreated with MEM-18 (1/500 dilution), an Ab that recognizes an epitope at or near the LPS binding site of CD14. At the end of the incubation period, media were collected and analyzed by ELISA for IL-8. Data are expressed as mean ± SEM of media collected from four individual wells for each condition in one of seven experiments with similar results. No statistically significant differences between LPB/sCD14 and LBP alone were seen at any point in this experiment. These findings have been replicated in HCASMC lines from seven different donors. C, Effect of PLC- on LPS-induced IL-8 release by HCASMC. HCASMC were grown to confluence in wells of a 48-well plate. At the beginning of the experiment, cells were washed with warm HBSS containing 1 µM HSA and then incubated for 2 h with 0.2 U/ml PLC- in SFM containing 0.1% HSA or with vehicle alone. After this preincubation, the cells were washed twice with HBSS/HSA to remove cleaved CD14 and other GPI-linked proteins. All sets of cells were then incubated for 24 h with 3 ng/ml LPS plus 100 ng/ml LBP. sCD14 (250 ng/ml) was added to some wells of PLC--treated cells. Media were collected and analyzed for IL-8 by ELISA. Data are expressed as nanograms of IL-8 per well and represent the mean ± SEM of four individual wells in one of two individual experiments with similar results. **, p = 0.005 compared with LBP without PLC-.

In inflammatory cells, CD14 also mediates responses to LTA, a product of Gram-positive bacteria that has recently been implicated in atherosclerosis (23, 24, 25). Therefore, we examined the effect of LTA on cytokine release in HCAEC and HCASMC. As was observed with endotoxin, LTA produced dose-dependent increases in IL-8 release in HCAEC only in the presence of sCD14 (Fig. 5A). In contrast, LTA produced dose-dependent increases in IL-8 release in HCASMC, and these responses did not require the addition of sCD14 (Fig. 5B).

View larger version (20K): [in this window] [in a new window]   FIGURE 5. HCASMC, but not HCAEC, respond to the CD14 ligand LTA in the absence of sCD14. A, HCAEC do not respond to LTA in the absence of sCD14. Confluent monolayers of HCAEC were incubated as described above in serum-free MEM, 0.1% HSA, 100 ng/ml LBP ± 250 ng/ml sCD14, and increasing concentrations (0–100 ng/ml) of LTA. Media were then collected and analyzed by ELISA for IL-8. *, p = < 0.05 vs 0 LTA; , p = < 0.05 vs LBP alone. B, HCASMC respond to LTA in the absence of sCD14. Confluent monolayers of HCASMC were incubated as described above. Media were collected and analyzed for IL-8 by ELISA. Data in both panels represent mean ± SEM of media from four individual wells for each condition in one of two experiments with similar results. Some SEM bars are smaller than the symbols in the figures.

Endotoxin signaling in EC is modulated by interaction with two serum proteins, LBP and sCD14. In healthy patients and those with low-grade infections, the molar ratio of LBP:sCD14 in serum is most commonly 1. Patients with chronic low-grade infections (e.g., periodontitis) appear to have chronically elevated levels of sCD14 (26), and increases in sCD14 are correlated with increased mortality in bacteremia (27). However, during the acute inflammatory response, while sCD14 levels increase slightly (2- to 3-fold), LBP levels increase by 10- to 30-fold (28). These high serum concentrations of LBP are believed to attenuate endotoxin signaling and limit the acute response, and have been shown to reduce mortality in experimental sepsis (29).

To determine whether alterations in the LBP:sCD14 ratio modulate the proinflammatory effects of low levels of endotoxin in coronary artery cells, cells were incubated in SFM containing 0.1% HSA, 60 ng/ml sCD14, 10 ng/ml LPS, and increasing concentrations of LBP (0–6 µg). Because of the similarity of the molecular masses of the two proteins (60 kDa for LBP, 55 kDa for sCD14), the ratio of the masses provides an approximation of the molar ratio. Fig. 6 shows the combined results from multiple experiments with HCAEC (not all LBP concentrations were tested in each experiment). The greatest IL-8 release was seen at low LBP:sCD14 ratios (0.1:1). Even a 1:1 molar ratio was somewhat less effective in promoting IL-8 release than the lowest ratios, whereas higher ratios (up to 10:1 in some experiments) were clearly inhibitory. A similar pattern was seen when the same HCAEC samples were assayed for MCP-1 levels (data not shown). A parallel series of experiments with HCASMC gave similar results (data not shown). These results indicate that the proinflammatory effects of endotoxin in HCAEC and HCASMC are maximal at the low LBP:sCD14 ratios characteristically seen in healthy patients or those with the chronic low-grade infections putatively linked to atherosclerosis.

View larger version (15K): [in this window] [in a new window]   FIGURE 6. LPS-induced IL-8 release is modulated by LBP/sCD14 ratio. HCAEC were incubated for 24 h at 37°C with serum-free MEM containing 0.1% HSA, 60 ng/ml sCD14, 10 ng/ml LPS, and increasing concentrations (0–240 ng/ml) of LBP. At the end of the incubation period, the media were collected and analyzed by ELISA for IL-8. Data are expressed as percentage of value obtained at a molar ratio of LBP/sCD14 of 1:1, and represent the mean ± SEM of the average values obtained in three to seven individual experiments. Similar results were seen in a series of six experiments with HCASMC. *, p = <0.05 vs 1:1 ratio; , p = < 0.01 vs 1:1 ratio.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

We demonstrate first that in HCAEC and especially in HCASMC, low levels of endotoxin potently induce release of the chemotactic cytokines IL-8 and MCP-1. These proinflammatory effects are thought to be critical to induction and progression of atherosclerosis in humans (30). IL-8 is chemotactic for neutrophils and activates NADPH oxidase in these cells, resulting in a local increase in reactive oxygen species (31). IL-8 also induces monocyte chemotaxis and converts monocyte rolling to firm adhesion on endothelial monolayers (32). MCP-1 has also been proposed to play a prominent role in atherosclerosis (30, 33), being highly expressed in human atherosclerotic plaques and likely playing a crucial role in monocyte recruitment into subendothelial lesions (33). In our studies, HCAEC were considerably more responsive than HUVEC in regard to cytokine release induced by endotoxin. In addition, we found that coronary artery SMC are remarkably sensitive to activation by endotoxin. Not only do the HCASMC release far greater amounts of inflammatory cytokines at any given LPS concentration than do HCAEC, but their threshold response occurs at 10–30 pg/ml LPS, as compared with 300–1000 pg/ml for HCAEC. These findings suggest that human vascular cells vary significantly in their responsiveness to endotoxin, which could have important implications in regard to the cellular sources of inflammation in atherosclerosis.

TLRs, a family of pattern recognition receptors involved in innate immune recognition of pathogen-associated molecules (e.g., endotoxin), are transmembrane proteins containing extracellular domains rich in leucine-repeat motifs and a cytosolic domain homologous to the IL-1R-signaling domain (34, 35). Among the TLR family, TLR4 is believed to be the specific endotoxin receptor (36, 37). TLR4 polymorphisms have been shown to play a role in atherogenesis, with the Asp²⁹⁹Gly mutation, which attenuates LPS signaling, associated with a decreased risk of atherosclerosis (38). TLR4 has been widely studied in monocytes and macrophages and was recently reported in human saphenous vein EC and SMC and tissues (14), human aortic EC (39), human microvascular EC (21, 39), coronary artery EC, (40), and saphenous vein SMC (41). Our finding of the presence of TLR4 in HCAEC and HCASMC (Fig. 2) is consistent with the potent endotoxin-induced inflammatory responses observed in the present study. However, differences in TLR4 expression in HCAEC vs HCASMC do not appear to account for differences in endotoxin responsiveness between these two cell types.

Monocytes and neutrophils respond to endotoxin through its interaction with mCD14, a 55-kDa GPI-anchored protein (42). Although it is generally believed that EC lack mCD14 and respond to endotoxin primarily through sCD14 circulating in blood, a recent report indicates that primary HUVEC express low levels of mCD14 (43). Also, Walton et al. recently reported the presence of mCD14 in human aortic EC, as detected by RT-PCR and a cell surface ELISA similar to ours (39). However, they did not demonstrate that the mCD14 conferred responsiveness to endotoxin in their aortic EC. It is conceivable that the lack of functional mCD14 expression in our HCAEC was because the cells were used at passage numbers 7–9. Because of the difficulty in procuring HCAEC, we were unable to perform experiments in primary cultured or early passage cells. However, our HCASMC lines, each of which expressed functional mCD14, were also used at passage numbers 7–9.

With respect to mCD14 expression in SMC, in the present study we found that seven different lines of HCASMC expressed mCD14 (Figs. 3 and 4), suggesting a possible mechanism for the striking endotoxin responsiveness in these cells. Loppnow et al. failed to find evidence of mCD14 expression in SMC isolated from human saphenous veins using RT-PCR, Northern analysis, cell-sorting analysis and immunoassay experiments (44), although these cells responded to 1–1000 ng/ml LPS in the presence of serum. It is uncertain whether these contrasting results are related to the vascular source of the SMC (saphenous vein vs coronary artery) or perhaps to differences in culture conditions.

Considering that HCASMC are capable of providing a vigorous defensive response to endotoxin by virtue of their expression of both mCD14 and TLR4, our findings suggest that HCASMC, the most abundant cell type in coronary arteries, likely play an important role in mediating vascular inflammation induced by endotoxin. Because CD14 recognizes a diverse array of inflammatory mediators and functions as a pattern recognition molecule in inflammatory cells (10), expression of functional CD14 in coronary artery SMC implies a potentially broader role for these cells in transducing innate immune responses in the vasculature. It may also be consistent with previous reports that have suggested a macrophage-like phenotype for some subpopulations of human intimal or neointimal SMC, based on their expression of the scavenger receptor CD36 (45, 46, 47). Our demonstration of functional mCD14 in HCASMC strongly implies a role for these cells in innate immunity, just as the presence of the scavenger receptor may imply a role for SMC in foam cell formation in atherosclerotic lesions.

LBP is a 60-kDa lipid/phospholipid binding and transfer protein (48, 49) that extracts endotoxin monomers from the bacterial membrane or from aggregates of circulating endotoxin, and subsequently delivers these molecules to CD14, resulting in target cell activation, or to lipoproteins, leading to hepatic clearance (50). The capacity of LBP to modulate endotoxin-induced activation of coronary artery cells has never been examined. Our results (Fig. 6) suggest that the optimal LBP:sCD14 ratio for HCAEC and HCASMC activation is <1:1, which is consistent with other reports showing that the transfer of endotoxin monomers by LBP to CD14 is catalytic in nature, with one molecule of LBP being able to transfer more than one LPS monomer to CD14 (48). Further, our results show that LBP:sCD14 ratios of 2:1 or greater inhibit activation, presumably promoting endotoxin clearance by delivering it to lower affinity binding sites. These findings are consistent with the recent report of Gutsmann et al. (51), who also found a concentration-dependent dual role for LBP in the activation of freshly isolated human mononuclear cells at low LBP levels, but an inhibition of activation at higher acute-phase LBP levels. To our knowledge, similar studies have never been reported in endothelial or vascular SMC. Although in vivo much of this inactivation produced by increased LBP levels would result from enhanced clearance by serum proteins and lipoproteins (50), our experiments were performed under serum-free conditions. This suggests that EC may themselves participate in endotoxin clearance, possibly through uptake and/or transcytosis mediated by caveolae or scavenger receptors. Because the chronic subacute infections implicated in atherosclerosis are associated with a lower LBP:sCD14 ratio, our findings suggest that the capacity of endotoxin to activate EC might be relatively greater in patients with these conditions.

In summary, we report in this study that low levels of endotoxin cause proinflammatory activation of HCAEC and HCASMC. HCASMC, which are remarkably responsive to endotoxin, likely contribute importantly to endotoxin-induced vascular inflammation. This striking responsiveness of HCASMC to low pg/ml levels of endotoxin may be due in part to expression of endogenous mCD14. We demonstrate that both HCAEC and HCASMC express TLR4, the putative endotoxin-signaling receptor. We also demonstrate that the degree of vascular cell activation by endotoxin is regulated by the molecular ratio of LBP and sCD14, two proteins thought to play a critical role in the initiation of the endotoxin-signaling pathway in vivo. Together, these findings provide novel insight into mechanisms by which low levels of circulating endotoxin might promote atherosclerosis in humans. More broadly, they suggest that vascular cells, especially vascular SMC, may play an active role in the innate immune response.

	Acknowledgments

 
We thank Shao-Ping Xu for assistance with the RT-PCR experiments.

	Footnotes

 
¹ This work was supported by HL-070860, HL-49264, and HL-62984 (to N.L.W.) from the National Institutes of Health, by American Heart Association Grants-in-Aid (to G.M.D. and W.-G.L.), and by a Merit Review Grant from Department of Veterans Affairs (G.M.D.).

² Address correspondence and reprint requests to Dr. Lynn L. Stoll, Division of Cardiovascular Diseases, Department of Internal Medicine, E317-C GH, University of Iowa, Iowa City, IA 52242. E-mail address: stolll{at}mail.medicine.uiowa.edu

³ Abbreviations used in this paper: EC, endothelial cells; CHO, Chinese hamster ovary; HCA, human coronary artery; HSA, human serum albumin; LBP, LPS-binding protein; LTA, lipoteichoic acid; mCD14, membrane-bound CD14; PLC-, phosphoinositide-specific phospholipase C; sCD14, soluble CD14; SFM, serum-free medium; SMC, smooth muscle cells.

Received for publication December 22, 2003. Accepted for publication April 26, 2004.

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