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Infection and Immunity, June 2001, p. 3772-3781, Vol. 69, No. 6
Division of Immunology and Gnotobiology,
Institute of Microbiology, Czech Academy of Sciences,
Víde
Received 29 August 2000/Returned for modification 26 October
2000/Accepted 12 March 2001
Human endothelial as well as epithelial cells were shown to respond
to lipopolysaccharides (LPSs). However, the expression and release of
CD14 by these so-called CD14-negative cells have not been studied in
detail. We investigated three human intestinal epithelial cell lines
(ECLs), SW-480, HT-29, and Caco-2, for their expression of CD14 and
CD11c/CD18 as well as their responsiveness to endotoxins.
Fluorescence-activated cell sorter analysis revealed no expression of
CD11c/CD18, but there was low expression of membrane-bound CD14 on
HT-29, Caco-2, and SW-480 ECLs. Both Western blotting and reverse
transcription-PCR confirmed the CD14 positivity of all three intestinal
ECLs. No substantial modulation of CD14 expression was achieved after
6, 8, 18, 24, and 48 h of cultivation with 10-fold serial
dilutions of LPS ranging from 0.01 ng/ml to 100 µg/ml. Interestingly,
soluble CD14 was found in the tissue culture supernatants of all three
ECLs. Finally, only HT-29 and SW-480, and not Caco-2, cells responded
to LPS exposure (range, 0.01 ng/ml to 100 µg/ml) by interleukin 8 release. Thus, we show that HT-29, SW-480, and Caco-2 human intestinal
ECLs express membrane-bound CD14. As Caco-2 cells did not respond to
LPS, these cell lines might be an interesting model for studying the
receptor complex for LPS. The fact that human intestinal epithelial
cells are capable not only of expression but also of release of soluble
CD14 may have important implications in vivo, e.g., in shaping the
interaction between the mucosal immune system and bacteria in the gut
and/or in the pathogenesis of endotoxin shock.
Endotoxin, the bacterial
lipopolysaccharide (LPS), is a characteristic outer membrane entity of
gram-negative bacteria and a potent inducer of inflammatory responses.
Exposure to even low amounts of LPS leads to a dramatic release of
inflammatory mediators that are thought to be responsible for the
deleterious effects in septic shock, such as refractory hypotension,
disseminated intravascular coagulation, and multiple organ failure,
causing the high mortality rate in gram-negative sepsis
(18).
Several cell surface structures such as CD11c/CD18, the scavenger
receptor, and the D-galactose receptor have been found to bind LPS, as have a number of serum components, namely, albumin, transferrin, bactericidal/permeability-increasing protein (BPI), and
high-density lipoproteins. Many of these are involved in LPS detoxification (reviewed in reference 45). On the other
hand, CD14, a 53-kDa glycosylphosphatidylinositol (GPI)-anchored
protein together with LPS-binding protein (LBP) have been shown to play a substantial role in LPS-mediated cell activation (31,
54). CD14 exists as a membrane GPI-anchored glycoprotein and a
soluble plasma protein. Both forms of CD14 were shown to be involved in LPS signaling and cell activation, characterized by induction of tumor
necrosis factor alpha (TNF- CD14 is primarily expressed on monocytes/macrophages but also on
polymorphonuclear as well as nonmyeloid cells such as B cells and
gingival fibroblasts (45, 47, 53, 56). Endothelial and
epithelial cell lines (ECLs) were used for studying the LPS effect on
CD14-negative LPS-sensitive cells (16, 23, 40). However,
the expression of mCD14 and thus also the release of sCD14 by these
cells have been only poorly investigated, usually by negative
immunohistochemical staining (45).
Protease-mediated shedding participates in generating sCD14, which
reaches concentrations in plasma of 2 to 6 µg/ml and is increased
together with levels of acute-phase proteins during sepsis (3,
47). The cellular source of sCD14 has not yet been clearly
identified, as patients with paroxysmal nocturnal hemoglobinuria, who
have a defect in GPI anchoring, do not express mCD14 on their monocytes
yet possess normal levels of serum sCD14 (9). Prolonged
exposure to LPS was reported to down-regulate membrane expression of
CD14 on monocytes (27). In vivo, intestinal epithelial
cells are continuously exposed to LPS in the gut and play an important
role in mucosal innate immunity.
These facts led us to investigate in more detail the presence of both
mCD14 and sCD14 as well as LPS activation of three human intestinal
ECLs, SW-480, HT-29, and Caco-2. In this study we report that CD14 is
expressed on, and more importantly also released as sCD14 by, human
intestinal epithelial cells.
Reagents and MAbs.
LPSs used in this study were the phenol
extract LPS from Escherichia coli serotype O55:B5, purified
by ion-exchange chromatography, and phenol-extracted LPS from
Salmonella enterica serovar Minnesota (Sigma, St. Louis,
Mo.). LPS suspensions were prepared as 2 mg of sonicates per ml in
pyrogen-free phosphate-buffered saline (PBS; Gibco BRL, Grand Island,
N.Y.). Human albumin (endotoxin, Cells and cell cultures.
HT-29, SW-480, and Caco-2 human
colonic adenocarcinoma cell lines were obtained from the European Type
Culture Collection (Salisbury, United Kingdom). HT-29 and Caco-2 human
ECLs were cultivated in Dulbecco's modified Eagle's medium (DMEM)
(Sigma) containing 4.5 g of glucose per liter and supplemented
with heat-inactivated 10% fetal bovine serum and 2 mM
L-glutamine, whereas SW-480 cells were grown in RPMI 1640 medium (10% fetal bovine serum, 2 mM L-glutamine) containing 2 g of glucose per liter. All complete media were
tested by the Limulus amebocyte lysate assay (Sigma) to be
free of endotoxin. No antibiotics were added to these media, and cell
lines were repeatedly screened for mycoplasma (PCR-based test; Statens
Serum Institut, Copenhagen, Denmark) with negative results. Cell
cultures were incubated at 37°C in humidified air maintained at 5%
CO2. The cells were grown in plastic tissue culture flasks
(Nunc, Roskilde, Denmark) and subcultured at confluence by employing
trypsin-EDTA (Sigma). For further assays, cells were plated into 6- or
24-well plates (Costar, Acton, Mass.) with 3 or 1 ml of medium,
respectively. On reaching confluence, the cells were rinsed with the
corresponding medium and incubated with 10-fold serial dilutions of
LPSs (E. coli serotype O55:B5, Salmonella serovar
Minnesota) ranging from 0.01 ng/ml to 100 µg/ml for 6, 8, 18, 24, and
48 h. Human albumin (Sigma) was used as a negative control.
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.6.3772-3781.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
CD14 Is Expressed and Released as Soluble CD14 by
Human Intestinal Epithelial Cells In Vitro: Lipopolysaccharide
Activation of Epithelial Cells Revisited
ková,1
ská 1083, 142 20 Prague 4, Czech
Republic,1 and Department of Pathology,
Nihon University School of Dentistry, 1-8-13 Kanda-Surugadai,
Chiyoda-ku, Tokyo 101, Japan2
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
), interleukin 1 (IL-1), IL-6, and IL-8
(7, 45). While membrane CD14 (mCD14) is involved in LPS
activation of CD14-positive cells via complexes of LPS and LBP
(21, 49, 54), soluble CD14 (sCD14) was shown to mediate
LPS activation on CD14-negative cells such as endothelial and
epithelial cells (4, 16, 23, 40, 45, 49). mCD14 is a
GPI-anchored protein; therefore, a transmembrane, signal-transducing molecule for LPS has been assumed for many years (45, 49, 50,
52). Human Toll-like receptor 2 and more recently Toll-like receptor 4 have been shown to mediate transmembrane LPS signaling by
utilizing the NF-
B signaling pathway in an LBP-dependent and CD14-enhancing manner (1, 11, 26, 32, 55). The importance of CD14 as a coreceptor for LPS was clearly demonstrated by inhibition studies using blocking anti-CD14 antibodies (Abs) (7, 27, 38,
51).
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
0.1 ng/mg) and
phosphatidylinositol-specific phospholipase C (PI-PLC) were purchased
from Sigma. Mouse anti-human CD14 monoclonal Abs (MAbs) MEM-15 and
MEM-18 (both immunoglobulin G1 [IgG1]) and IN-05 mouse anti-insulin
(IgG1) MAb were kindly provided by V. Ho
ej
í
(Institute of Molecular Genetics, Czech Academy of Sciences Prague,
Czech Republic). Compared to the MEM-15 anti-human CD14 MAb, the MEM-18
MAb displays a much greater inhibitory capacity on LPS-induced
activation of CD14-positive cells (7). Other mouse
anti-human CD14 MAbs, MoP9, MoP15, and MoS39, were obtained from the
CD14 panel of the 4th Human Cluster of Differentiation Workshop
(provided via V. Hoejí). Fluorescein
isothiocyanate (FITC)-conjugated anti-CD11c and
R-phycoerythrin (PE)-conjugated anti-CD18 MAbs were
purchased from Immunotech (Marseille, France). Biotinylated (Amersham,
Little Chalfont, Buckinghamshire, United Kingdom) and FITC-conjugated
goat anti-mouse IgG F(ab')2 Ab and peroxidase-conjugated
streptavidin (Immunotech) were used in secondary and tertiary labeling
steps, respectively.
), as
described by Zweibaum et al. (57). In brief, HT-29 cells were cultivated in a special glucose-free DMEM (prepared at the Institute of Molecular Genetics, Czech Academy of Sciences),
supplemented with 10% fetal bovine serum and 2 mM
L-glutamine. After 20 days the surviving, selected HT-29
cells were subcultured using trypsin-EDTA (Sigma) and cultivated for
the next three passages with a doubling time of approximately 5 days.
At confluence, these differentiated, slowly growing HT-29
Glc cells were then examined for their expression of CD14.
FACS analysis. Cell suspensions were prepared from confluent cells growing as monolayers in six-well plates (Costar) and detached from the surface using PBS with 0.02% EDTA (Sigma). Cells (5 × 105 cells per sample) were then used for direct or indirect immunofluorescence staining. Thus, epithelial cells were incubated for 30 min with the mouse anti-human CD14 MAb MEM-15 or MEM-18 at a 1:500 dilution and then incubated for 30 min with secondary FITC-conjugated, goat anti-mouse IgG F(ab')2 at a 1:200 dilution (Immunotech). For direct immunofluorescence staining, cells were incubated with FITC-conjugated mouse anti-human CD11c or PE-conjugated mouse anti-human CD18 MAbs (Immunotech). FITC- and PE-conjugated isotype-matched (IgG1) antibodies (Immunotech) were used as controls. Furthermore, in order to exclude any nonspecific staining, both MEM-15 and MEM-18 anti-CD14 MAbs were tested on a CD14-negative human erythroblastic cell line, K562. Through the whole staining procedure cells were kept on ice in PBS containing 0.02% EDTA, 2% gelatine, and 0.01% NaN3 (Sigma) and were washed twice between each step. Fluorescence was measured on a FACScan (Becton Dickinson & Co., San Jose, Calif.), and data respecting 10,000 live cells from each sample were collected according to the propidium iodide (FL-3) discrimination method. Changes in mean fluorescence intensity (MFI) were analyzed by WinMDI software version 2.8.
SDS-PAGE and Western blotting. Confluent epithelial cells were washed three times in corresponding culture media without fetal bovine serum, and 107 cells were incubated with 2 U of PI-PLC per ml in PBS at 37°C for 1 h. After centrifugation for 20 min at 1,000 × g, this GPI protein-enriched cell-free supernatant (as described by Pugin et al. [40]) was diluted in sample buffer (50 mM Tris-HCl [pH 7.6], 150 mM NaCl, and 10 mM EDTA, with a cocktail of the protease inhibitors aprotinin, phenylmethylsulfonyl fluoride, and leupeptin) (Sigma and Boehringer Mannheim, Mannheim, Germany) and heated at 90°C for 10 min, and 20 µl of each sample in 2% sodium dodecyl sulfate (SDS) was subjected under nonreducing conditions to SDS-10% polyacrylamide gel electroforeseis (PAGE) in the discontinuous buffer system of Laemmli (28). For detection of sCD14, cell-free supernatants which were obtained after 48 h of cell culture were concentrated three times on Centricon-10 concentrators (Amicon, Inc., Beverly, Mass.) and similarly assessed by SDS-10% PAGE. Separated proteins were transferred to nitrocellulose (Schleicher & Schuell, Feldbach, Germany) using a transblot cell (Bio-Rad, Hercules, Calif.). The nitrocellulose strips were blocked in PBS containing 2% low-fat milk (PBS-M) and 0.05% Tween 20 (Serva, Heidelberg, Germany) for 1 h and then incubated with a panel of primary anti-CD14 MAbs (MEM-15, MEM-18, MoP9, MoP15, and MoS39 at a dilution of 1:500 in PBS-M) as well as IN-05 mouse anti-insulin (IgG1) isotype control MAb (at a dilution of 1:200 in PBS-M), followed by biotinylated goat anti-mouse IgG F(ab')2 Ab (1:1,000 dilution in PBS-M; Amersham) and peroxidase-conjugated streptavidin (1:200 dilution in PBS-M; Immunotech). The strips were washed three times in PBS with 0.05 Tween 20 after each step. Marked proteins were visualized by the enhanced-chemiluminescence detection system (Amersham).
RT-PCR and sequencing of PCR products. Total RNA was isolated with Trizol (Gibco BRL), and single-stranded complementary cDNA was synthetized using 1 µg of total RNA and 200 U of Superscript II reverse transcriptase (Gibco BRL) in a solution containing 50 mM Tris-HCl (pH 8.3), 75 mM KCl, 3 mM MgCl2, 10 mM dithiothreitol, a 1.5 µM concentration of oligo(dT)12-18 primers, and a 0.5 mM concentration of each deoxynucleoside triphosphate for 1 h at 37°C followed by 5 min at 75°C. Subsequently, 2 µl of cDNA was specifically amplified by PCR with 2.5 U of Taq DNA polymerase (Top-Bio, Prague, Czech Republic) in a solution containing 10 mM Tris-HCl (pH 8.8), 50 mM KCl, 1.5 mM MgCl2, 0.2 mM each deoxynucleoside triphosphate, and 0.5 µM each primer. The PCR conditions were as follows: 94°C for 1 min; 35 cycles of 94°C for 45 s, 57°C for 45 s, and 72°C for 2 min; and 72°C for 10 min as a final extension. Two sets of human-CD14-specific primers were used. The first one consisted of sense 5' GCT GGA CGA TGA AGA TTT CC 3' and antisense 5' ATT GTC AGA CAG GTC TAG GC 3' primers with expected product sizes of 535 bp. Contamination with genomic DNA was checked by omitting the Superscript II during reverse transcription (RT). Amplification without cDNA was carried out to assess later contaminations. The fact that the human CD14 gene contains a single intron after the initiation codon (15) has allowed us to design a set of spanning primers which give products of different sizes from genomic DNA and mRNA, 356 and 284 bp, respectively. The sequences of the primers were 5' GCT GTG TAG GAA AGA AGC TA 3' (sense) and 5' TTT AGA AAC GGC TCT AGG TTG 3' (antisense) (Genset, Paris, France). The PCR products and 100-bp PCR marker (Sigma) were run on 1.5% agarose gels stained with ethidium bromide and visualized with a UV transilluminator (UVP, Upland, Calif.). All amplifications, including RTs, were repeated at least three times.
Results were confirmed by manual sequencing of purified and cloned RT-PCR products obtained from the HT-29 ECL. Briefly, the band of interest (284 bp) was cut out from the agarose gel, boiled for 10 min, ethanol precipitated, and reamplified with the same set of primers and a trace of [-32P]dCTP (NEN, Boston, Mass.). Two
microliters of the PCR mixture was then subjected to single-strand
conformation polymorphism analysis on native polyacrylamide gel (5%
acrylamide, 5% glycerol; Sigma) at 5 W for 12 h. After
autoradiography, the major purified band was cut out from the unfixed
polyacrylamide gel, rereamplified by PCR, and cloned into the pCR2.1
vector using a TA cloning kit with INVF' competent cells from
Invitrogen (San Diego, Calif.). Isolated plasmid DNA was sequenced by
using the M13 (
20) forward primer and a T7 sequencing kit from
Pharmacia Biotech (Uppsala, Sweden).
IL-8 ELISA. The interleukin 8 (IL-8) concentration was determined in the undiluted cell culture supernatants collected after 8 and 24 h of cultivation with an enzyme-linked immunosorbent assay (ELISA) DuoSet kit from Genzyme (Cambridge, Mass.). The sensitivity of this assay was 20 pg/ml. An additional human IL-8 standard (1 µg/ml) was kindly provided by M. Ceska (Sandoz Forschungsinstitut, Vienna, Austria) and used in parallel. All experiments were performed in 96-well flat-bottom Immuno-Maxisorp microtiter plates (Nunc). O-Phenylenediamine (Sigma) was used as a substrate for peroxidase, and absorption was measured with a Uniskan II microplate reader (Labsystems, Helsinki, Finland) at 405 nm.
NO production. Nitric oxide (NO) production was assessed as nitrite formation in 50 µl of cell culture supernatants. Samples were incubated for 10 min at 37°C with Griess reagent (1% sulfanilamide, 0.1% naphtylethylendiamine, 2.5% H3PO4) and measured at 540 nm with a Uniskan II microplate reader (Labsystems).
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Detection of CD14 on the human intestinal SW-480, HT-29, and Caco-2
ECLs by FACS, Western blot, and RT-PCR analyses.
The cell surface
expression of the LPS receptors CD14 and CD11c/CD18 on SW-480, HT-29,
and Caco-2 human ECLs was first assessed by flow cytometry. FACS
analysis revealed positivity for mCD14 on HT-29 and Caco-2 cell lines
with MFIs of 10.4 and 18.2, respectively (Fig.
1). Only very low positivity for mCD14
was detected on the SW-480 ECL. The three cell lines were found
negative for both CD11c and CD18, thus excluding expression of another
LPS-signaling receptor, CD11c/CD18 (e.g., see the data for CD18
staining shown in Fig. 1). All FACS experiments were repeated at least
two times but on average were repeated four to five times, and two
anti-CD14 MAbs, MEM-15 and MEM-18, were used in parallel.
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Effect of differentiation stage of epithelial cells on CD14
expression.
The three ECLs SW-480, HT-29, and Caco-2, when
cultivated under standard conditions, represent good models as concerns
the stage of differentiation of epithelial cells. The most
undifferentiated cell line, SW-480, showed very low but detectable
surface expression of CD14 (Fig. 1 and 2), whereas the most
differentiated cell line, Caco-2, displayed the highest surface
expression of CD14 (MFI, 18.2) as documented by FACS analysis (Fig. 1
and 5A). In order to further evaluate a
relation between the differentiation stage of epithelial cells and
their expression of mCD14, HT-29 cells were cultivated in
Glc DMEM. The absence of glucose leads to the structural
and enzymatic differentiation of selected HT-29 cells as described by
Zweibaum et al. (57). Both RT-PCR and Western blot
analyses revealed clear CD14 expression on both undifferentiated and
differentiated HT-29 cells (Fig. 4 and 5B). FACS analysis revealed no
substantial differences in the levels of mCD14 expression between HT-29
and differentiated HT-29 Glc cells (Fig. 5A).
|
Modulation of CD14 expression on SW-480, HT-29, and Caco-2
epithelial cells.
Figure 6a shows a
constant presence of CD14 mRNA in the HT-29 cell line, irrespective of
exposure to different doses of LPS. FACS analysis was employed for the
final quantification of modulation of CD14 expression on the three
ECLs. No remarkable differences measured as a shift in MFI (FL-1) were
observed after cultivating the three epithelial cell lines with LPS
from E. coli serotype O55:LB5 or Salmonella
serovar Minnesota for 6, 18, 24, or 48 h. Taking into account the
massive exposure of human enterocytes to LPS in the gut, quite high
doses of LPSs were also included in our experiments, with
concentrations from 0.01 ng/ml to 100 µg/ml. All experiments were
repeated in at least two independent cell cultures, and the same
concentrations of human albumin were used as negative controls.
However, no substantial modulation of CD14 expression was recorded in
any of the above-mentioned cultivating arrangements (some data are
presented in Fig. 6B).
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Human intestinal ECLs release sCD14 into supernatants.
As
sCD14 plays important roles in activation of both CD14-negative and
CD14-positive cells and its cellular source remains unknown, we
investigated the presence of sCD14 in the cell-free tissue culture
supernatants of the three ECLs. Interestingly, SDS-PAGE and Western
blot detection revealed a clear positivity for sCD14 in cell-free 48-h
culture supernatants from SW-480, HT-29, and Caco-2 as well as HT-29
Glc ECLs. Supernatants from the differentiated HT-29
Glc ECL cultivated in glucose-free medium have repeatedly
revealed a higher background than those from the SW-480, Caco-2, and
HT-29 ECLs (Fig. 7). The spontaneously
released form of CD14 displayed a typical multiple-band pattern of 53 and 48 kDa (Fig. 7) as described by Ba
il et al. (2,
3). SW-480 cells with the lowest expression of surface mCD14
were also characterized by a weak release of sCD14 into the
supernatant, especially as regards the smaller band, corresponding to
the protease-shed CD14 (2, 3) of about 48 kDa (Fig. 7).
|
Activation of human intestinal epithelial cells by LPS.
Both
SW-480 and HT-29 cell lines released IL-8 in response to 10-fold
concentrations of LPS (E. coli O55:LB5) ranging from 0.01 ng/ml to 100 µg/ml. A slight increase in the amount of IL-8 in
supernatants was observed after 24 h of cultivation compared to
that after 8 h (Fig. 8). Although
the amount of IL-8 displays a dose dependency in both cell lines, the
highest dose of 100 µg of LPS per ml already had an inhibitory
effect. On the other hand, no LPS-induced production of IL-8 was
detected in any of these cultivation arrangements with Caco-2 cells
(Fig. 8). In order to further investigate the activation of epithelial
cells by LPS, production of NO measured as nitrite production was
assessed. However, no detectable NO production was found in SW-480,
HT-29, or Caco-2 epithelial cells exposed to LPS (data not shown).
Thus, although all three cell lines express surface mCD14, only the SW-480 and HT-29 cell lines responded by IL-8 release to exposures to
different doses of LPS.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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In this study we demonstrate for the first time that CD14 is expressed as well as released as sCD14 from human intestinal epithelial cells. CD14 was detected on SW-480, HT-29, and Caco-2 human intestinal ECLs on both the protein and mRNA levels (Fig. 1 to 4). Its membrane expression was confirmed by repeated FACS and Western blot analyses using multiple anti-CD14 MAbs (Fig. 1 and 3). Interestingly, a soluble form of CD14 was detected in cell-free cell culture supernatants from all three ECLs (Fig. 7). Furthermore, only SW-480 and HT-29 and not Caco-2 ECLs were sensitive to LPS (Fig. 8).
CD14 expression has been reported on nonmyeloid cells, such as B cells,
or gingival fibroblasts (45, 47). On the other hand, the
astrocytoma cell line U373, smooth muscle cells, endothelial cells, and
epithelial cells were used in studies dealing with LPS-mediated
activation of CD14-negative cells via the sCD14 pathway (4, 16,
33, 40, 41, 45). However, unlike for smooth muscle cells
(33), the expression of CD14 on human epithelial cells was
not studied in detail. Our results showing that human intestinal
adenocarcinoma ECLs express mCD14 (Fig. 1 to 4) are in agreement with
and extend data gained at the mRNA level from other species. Thus,
Diamond et al. (8) reported that bovine tracheal
epithelial cells express CD14 mRNA. An in vivo study of mice showed
extramyeloid, LPS-induced expression of CD14 mRNA in epithelial cells
from several organs such as lung, kidney, and liver (12).
In addition, the up-regulation of CD14 mRNA was shown to be mediated
also by TNF- and IL-1
(13, 14). No studies
concerning the expression of CD14 mRNA by nonneoplastic human
intestinal epithelial cells have been published.
Another cell surface molecule known to bind LPS, the 2 integrin of
CD11c/CD18, was first considered in LPS clearance and detoxification
(52). Later, CD11c/CD18 was reported to mediate an
activation signal after exposure to LPS (25). The cell
activation was not dependent on the presence of sera, and thus its role
in infected tissues was proposed (25). We wish to point
out, however, that no expression of CD11c or CD18 was detected on
HT-29, SW-480, and Caco-2 human intestinal ECLs (Fig. 1).
Several studies reported, although with certain controversy,
LPS-induced changes in the level of CD14 expression on myeloid cells.
These effects occurred within a relatively short period of time (1 to
6 h) and were documented on both the protein and mRNA levels
(3, 10, 34, 35, 56). In our hands, no substantial modulation of CD14 expression was observed in the three ECLs, in spite
of our using a wide range of LPS doses as well as timings (some data
are presented in Fig. 6). We think that this may be due to the
differences in levels of LPS-induced CD14 expression in myeloid cells
compared to that in epithelial cells, in which TNF- participates in
mediating CD14 gene expression (13). Although the three
epithelial cell lines express mCD14 at levels correlating with their
degree of differentiation (SW-480 < HT-29 < Caco-2) (Fig.
1), we were not able to induce a substantial increase in the level of
mCD14 by differentiating the HT-29 cell line in glucose-free medium
(57) (Fig. 5A).
The most differentiated, mCD14-positive ECL, Caco-2, which represents
the closest model of in vivo enterocytes, does not secrete IL-8 after
stimulation with LPS (Fig. 8) (10). It is of interest, however, that sodium butyrate, a metabolic product of intestinal bacterial fermentation of carbohydrates, enables IL-8 secretion in
response to LPS as well as significantly enhancing IL-1-induced IL-8
secretion by Caco-2 cells (17). Thus, additional stimuli, such as from physiological intestinal microflora, are necessary to
promote LPS's effect on Caco-2 cells. Our recent experiments have
shown that the blocking anti-CD14 MAb MEM-18 significantly reduced
LPS-induced IL-8 release in both HT-29 and SW-480 ECLs, pointing to the
involvement of mCD14 in their activation (unpublished data).
The fact that only SW-480 and HT-29, but not Caco-2, mCD14-positive ECLs responded to LPS by IL-8 release (Fig. 8) makes them a promising tool in studies of the role of the multiple receptor complex for LPS. The Toll-like 4 receptor was clearly shown as a trans-membrane signaling molecule for CD-14-enhanced LPS activation (1, 11, 32). Nevertheless, signal transduction via the GPI anchor, a component of glycolipid-reach microdomains, which are associated with cytoplasmic protein tyrosine kinases and G proteins (5, 24), cannot be ruled out, especially for CD14 receptor cross-linking (39).
Although LPS-induced production of NO was reported in myeloid and endothelial cells (44, 45), we observed no such effect with the intestinal ECLs. These data confirm the previous results of Salzman et al. (43), who documented that an additional stimulus, e.g., gamma interferon, is required for promoting LPS-induced NO production by epithelial cells.
Of interest is our finding that all three intestinal ECLs released
soluble forms of CD14 (Fig. 7). In accordance with data published by
Bail and Strominger (3), sCD14 displayed a two-band pattern of 48 and 50 kDa on SDS-PAGE (Fig. 7). While the smaller form
of 48 kDa has been considered a product of protease-mediated shedding,
the 50-kDa band has been suggested to represent a directly released
form of sCD14 (2, 3). Previous studies have shown opposite, dose-dependent effects of sCD14 on the activation of mCD14-positive cells (22) as well as its involvement in
activating CD14-negative cells (16, 23, 40). Thus, sCD14,
together with other LPS-binding factors such as LBP, BPI, and
high-density lipoproteins, is thought to play a central role in
regulating responses to encountered gram-negative bacteria
(22).
It is generally known that human enterocytes in vivo do not express
mCD14 at levels detectable by immunohistochemistry (40, 45,
46). However, taking into account the number of epithelial cells
in the mucosal compartment and the fact that polarized, basolateral
secretion of various cytokines, e.g., chemokines as well as acute-phase
plasma proteins, was described for human ECLs (29, 37),
even relatively low levels of release of sCD14 might maintain its level
in serum. Several mechanisms can contribute to the decrease or loss of
mCD14 expression. While monocytes and endothelial cells are activated
by LPS during infection, intestinal epithelial cells are continuously
exposed to LPS from gut microflora under physiological conditions.
Prolonged exposure to LPS was shown to down-regulate mCD14 expression
on monocytes and to establish LPS tolerance (27).
Furthermore, the anti-inflammatory cytokines IL-4, a prevalent cytokine
of the mucosal microenvironment, and IL-13 were reported to
down-regulate CD14 expression on monocytes (6, 30).
Interestingly, human lamina propria macrophages almost do not express
mCD14 (19, 46) unless inflammation is present, such as in
inflammatory bowel disease (20, 42) or celiac disease
(48). In mice, TNF- and IL-1 were shown to induce
CD14 mRNA in nonintestinal epithelial cells (13, 14). In
addition, Meijssen et al. reported expression of CD14 mRNA in
intestinal epithelial cells of IL-2/ mice, which
develop inflammatory bowel disease resembling human ulcerative colitis
(36). These data suggest that the healthy mucosal
microenvironment down-regulates mCD14 expression but that inflammatory
processes lead to its up-regulation (13, 14, 19, 20, 36, 42,
46).
Our observations that human intestinal ECLs express and release CD14 raise the possibility that enterocytes may be a source of sCD14 in humans. In conclusion, we suggest that the ability of intestinal epithelial cells to express and release CD14 may be of importance in maintaining the intricate balance between "self" and the external environment in the gut.
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ACKNOWLEDGMENTS |
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We gratefully thank V. Hoejí for kindly
providing us with anti-human CD14 (MEM-15, MEM-18) and anti-insulin
IN-05 MAbs. We also thank M. Ceska for an additional IL-8 standard, as
well as Petr Klement and Knud Josefsen for their help with SDS-PAGE and
molecular biology techniques, respectively. P. Kaparová and D. Horáková are thanked for excellent technical
assistance, and James Harries is thanked for his help in the
preparation of the manuscript.
This work was supported by grants A7020808, A7020716, and C6020801 from the grant agency of the Czech Academy of Sciences; grants VS96149 and KONTAKT178 from the grant agency of the Ministry of Education; grant 306/98/0433/00/1373 from the grant agency of the Czech Republic; and a grant from the EU project QLGI-1999-00050.
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FOOTNOTES |
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* Corresponding author. Mailing address: Autoimmunity and Transplantation Division, The Walter and Eliza Hall Institute of Medical Research, The Royal Melbourne Hospital PO, Parkville, 3050 Victoria, Australia. Phone: 61-3-93452563. Fax: 61-3-93470852. E-mail: pdfunda{at}hotmail.com or funda{at}wehi.edu.au.
Editor: R. N. Moore
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Infection and Immunity, June 2001, p. 3772-3781, Vol. 69, No. 6
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.6.3772-3781.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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