Previous Article | Next Article 
Infection and Immunity, March 2001, p. 1329-1336, Vol. 69, No. 3
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.3.1329-1336.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Clostridium difficile Toxins Disrupt
Epithelial Barrier Function by Altering Membrane Microdomain
Localization of Tight Junction Proteins
A.
Nusrat,1,*
C.
von Eichel-Streiber,2
J. R.
Turner,3,4
P.
Verkade,5
J. L.
Madara,1 and
C.
A.
Parkos1
Epithelial Pathobiology Research Unit,
Department of Pathology, Emory University School of Medicine,
Atlanta, Georgia1; Institut fur
Medizinische Mikrobiologie und Hygiene, Universität Mainz,
Mainz,2 Cell Biology and Biophysics
Program, EMBL, Heidelberg,3 and Max
Planck Institute of Molecular Cell Biology and Genetics,
Dresden,4 Germany; and Department of
Pathology, Wayne State University, Detroit, Michigan5
Received 28 July 2000/Returned for modification 14 September
2000/Accepted 20 November 2000
 |
ABSTRACT |
The anaerobic bacterium Clostridium difficile is the
etiologic agent of pseudomembranous colitis. C. difficile
toxins TcdA and TcdB are UDP-glucosyltransferases that monoglucosylate
and thereby inactivate the Rho family of GTPases (W. P. Ciesla,
Jr., and D. A. Bobak, J. Biol. Chem. 273:16021-16026, 1998).
We utilized purified reference toxins of C. difficile,
TcdA-10463 (TcdA) and TcdB-10463 (TcdB), and a model intestinal
epithelial cell line to characterize their influence on tight-junction
(TJ) organization and hence to analyze the mechanisms by which they
contribute to the enhanced paracellular permeability and disease
pathophysiology of pseudomembranous colitis. The increase in
paracellular permeability induced by TcdA and TcdB was associated with
disorganization of apical and basal F-actin. F-actin restructuring was
paralleled by dissociation of occludin, ZO-1, and ZO-2 from the lateral
TJ membrane without influencing the subjacent adherens junction
protein, E-cadherin. In addition, we observed decreased association of actin with the TJ cytoplasmic plaque protein ZO-1. Differential detergent extraction and fractionation in sucrose density gradients revealed TcdB-induced redistribution of occludin and ZO-1 from detergent-insoluble fractions constituting "raft-like" membrane microdomains, suggesting an important role of Rho proteins in maintaining the association of TJ proteins with such microdomains. These toxin-mediated effects on actin and TJ structure provide a
mechanism for early events in the pathophysiology of pseudomembranous colitis.
| |
INTRODUCTION |
Clostridium difficile is
an anaerobic bacterium that is a causative agent of
antibiotic-associated diarrhea. Disease etiology is primarily linked to
the bacterial production of two exotoxins referred to as toxins A and
B. C. difficile toxins A and B, also referred to as
TcdA-10463 (TcdA) and TcdB-10463 (TcdB), are large monomeric proteins
toxins that have ~45% amino acid identity and have
Mrs of 308,000 and 270,000, respectively
(50). Although the precise mechanisms by which these
toxins induce disease are incompletely understood, the intracellular
targets of the toxins in epithelial cells have been well described.
Both toxins disrupt the function of the Rho family of
low-molecular-weight GTP binding proteins including Rho, Rac, Cdc42,
and Rap in the case of TcdA. They do so by using UDP-glucose as a
cosubstrate and monoglucosylating these proteins (1, 10, 24,
25). Since Rho, Rac, and Cdc42 play a crucial role in regulating
the organization of the actin cytoskeleton (17), their
inactivation is associated with dysregulation of the cytoskeletal
network. The C. difficile toxins have been previously
documented to influence barrier function in intestinal epithelial cells
(19, 20). In addition, we have previously utilized a
chimeric DC3B toxin that specifically ADP-ribosylates and inactivates
Rho function without influencing Rac and Cdc42. Incubation of
epithelial cells with DC3B was associated with altered apical F-actin
organization and disruption of epithelial barrier function
(34). While the molecular basis of these observations is
not known, it is clear that the apical perijunction F-actin ring is
closely associated with tight junctions (TJs) (31). TJs
play an important regulatory role in barrier function, and numerous
proteins have been identified in this region. For example, occludin and
claudin(s) are integral membrane proteins believed to associate with
the apical perijunction F-actin ring via cytoplasmic plaque proteins
such as ZO-1 (11, 13-15, 40, 47, 48). The hyperphosphorylated form of occludin that is of high molecular weight
(HO) is believed to represent a key functional component of the TJ
(54). Recent evidence suggests that the functional components of TJs partition into specific membrane microdomains (36). Utilizing a differential detergent extraction and
sucrose density gradient approach, we have recently shown that HO and ZO-1 reside in membrane microdomains with characteristics of membrane "rafts" or detergent-insoluble glycolipid rafts (DIGs)
(36). Such "Raft"-like membrane microdomains contain
sphingolipid and cholesterol assemblies and serve to recruit specific
membrane proteins. These cholesterol-enriched membrane domains have
previously been defined on the basis of biochemical isolation
properties and more recently by utilizing fluorescence resonance energy
transfer microscopy and chemical cross-linking studies (2, 4, 5, 7, 12, 18, 41, 43, 49). Other important cellular components
associated with glycolipid rafts include signal transduction proteins
and a 21 to 24-kDa scaffolding protein, caveolin. For example, we have
recently observed that caveolin-1 focally coassociates with occludin in
functionally intact TJs (36).
From the above observations, it is clear that the relationship of
structural elements of TJ with the actin cytoskeleton is complex and
highly regulated. There is abundant evidence that key regulatory
elements include both the heterotrimeric GTP binding proteins and the
small GTP binding proteins of the Rho and Rab subfamilies (9, 23,
34, 52). In this study we examined the effects of TcdA and TcdB
on TJ structure and function in model T84 intestinal epithelial cells.
Such studies will shed further light on the influence of
Rho-inactivating toxins on TJ structure and function. T84 cells have
phenotypic characteristics of crypt intestinal epithelial cells and
form well-developed TJs when grown as a monolayer (33).
Incubation of T84 monolayers with TcdA or TcdB was associated with
marked changes in F-actin organization and TJ disruption. A key
cytoplasmic plaque TJ protein, ZO-1, was displaced from a Triton X-100
(TX-100)-insoluble raft containing membrane microdomain to a
TX-100-soluble pool, and a decrease in high-molecular-weight occludin
was observed following incubation of T84 monolayers with the TcdA and
TcdB toxins. The TcdAB-induced effects on TJ structure and function
were paralleled by disorganization of F-actin in the apical and basal
poles of epithelial cells. The global disorganization of F-actin
induced by TcdAB contrasts with the effects of another bacterial toxin,
C3 transferase, which specifically ADP-ribosylates Rho and influences
the apical F-actin pool and TJ function. Our results suggest that the
TcdAB toxins either directly or indirectly influence TJ function and
modulate both the membrane microdomain localization of TJ proteins and the affiliation of TJs with the underlying actin cytoskeleton.
| |
MATERIALS AND METHODS |
Cell culture and electrophysiology.
T84 cells (ATCC CCL-248)
were passaged and grown on collagen-coated permeable supports as
previously described (33, 38). Cells (passages 50 to 90)
were grown in a 1:1 mixture of Dulbecco's modified Eagle's medium and
Ham's F-12 medium supplemented with 15 mM HEPES buffer (pH 7.5), 14 mM
NaHCO3, 40 µg of penicillin per ml, 8 µg of ampicillin
per ml, 90 µg of streptomycin per ml, and 5% newborn calf serum.
C. difficile reference toxins TcdA-10463 (TcdA) and
TcdB-10463 (TcdB) were purified and utilized for these studies
(24, 25). Monolayers were incubated with TcdA and TcdB in
serum-free, antibiotic-free cell culture medium and applied to the
apical and basolateral surfaces of epithelial cells. Control monolayers were incubated with serum-free, antibiotic-free cell culture medium only.
Transepithelial resistance to passive ion flow was measured as
described previously (
30,
37,
38,
44). The apical and
basolateral reservoirs of monolayers grown on filters were connected
to
calomel and Ag-AgCl electrodes via agar bridges. A voltage
clamp was
used to determine the voltage response to a current
pulse of 25 µA.
Transepithelial resistance was then calculated
using Ohm's law.
Sieving characteristics of monolayers was examined
by flux studies
using the radiolabeled extracellular space marker
mannitol (3.6 Å).
[
3H] mannitol was added to the apical chamber of
monolayers accompained
by excess cold tracer to both sides of the
monolayer. Fluid aliquots
were obtained from the "cold" side every
20 min for 120 min under
control (medium-only) and experimental
(Tcd-incubated monolayers)
conditions. Samples were taken from the
"hot" side of monlayers
at the end of each experiment. Samples were
then added to scintillation
fluid and counted. The unidirectional flux,
J, was determined
by
J = dpm/(specific
activity × surface area × incubation time)
(
32).
Immunoprecipitation and Western blotting.
ZO-1, actin, and
occludin were immunoprecipitated from TcdB-incubated and control
(medium-only) T84 monolayers with polyclonal antibodies (Zymed, Inc.,
and Sigma) and protein A-Sepharose, using solubilized cell lysate as
described below. Briefly, monolayers grown to confluence on
5-cm2 permeable supports were isolated by scraping with a
Teflon spatula into Hanks balanced salt solution (HBSS) containing 1%
n-octylglucoside with protease inhibitors, followed by
low-speed centrifugation (2,000 × g; Beckman GS-6R
centrifuge) for 10 min. Cell extracts were subsequently incubated with
primary antibodies (~10 µg/ml) for 3 h at 4°C followed by protein
A-Sepharose (Pharmacia, Piscataway, N.J.) (20 µl of beads) for 3 h at 4°C. Immunoprecipitated proteins were denatured in sample buffer
and subjected to sodium dodecyl sulfate-polyacrylamide gel
electrophoresis and Western blotting using standard methods as
previously described (21, 35).
Isolation of detergent-insoluble glycolipid rafts by sucrose
gradient fractionation.
T84 cells were grown on 45-cm2
permeable supports (33) and incubated with or without TcdB
(80 ng/ml) for 2 h in cell culture medium. Two confluent
monolayers per condition were rinsed in HBSS, and cells were isolated
by scraping with a Teflon spatula into HBSS containing 1% TX-100 and
protease inhibitors (5 mM diisopropylfluorophosphate, 1.25 µM
phenylmethylsulfonyl fluoride, 10 µg each of leupeptin and
chymostatin per ml, 10ug/ml and 10 µM aprotinin) and homogenized using a Dounce homogenizer. After the sucrose concentration of the
lysate was adjusted to 40%, it was placed in the bottom of an
ultracentrifuge tube and overlaid with a 5 to 30% (weight/weight) linear sucrose gradient as previously described (36). The
gradients were subjected to ultracentrifugation (19 h at 39,000 rpm at
4°C) in a Beckman SW41 rotor, fractionated, and analyzed for sucrose concentration, light scattering at 600 nm, and alkaline phosphatase activity by previously described procedures (5, 26, 41, 53). Distribution of TJ proteins (ZO-1 and occludin) and the membrane raft (DIG)-associated protein caveolin-1 was determined by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western
blotting. Antibodies to the above proteins were obtained from Zymed
Inc., Transduction Labs, and Santa Cruz, respectively.
Immunofluorescence, immunogold labeling, and electron
microscopy.
Monolayers of T84 cells were washed in HBSS, fixed in
ethanol at 
20°C for 20 min, incubated with the respective primary
antibodies to occludin, ZO-1, or ZO-2 for 60 min in a humidity chamber,
washed, and incubated with fluorescein isothiocyanate-conjugated
secondary antibodies (Jackson Labs). Monolayers mounted in
p-phenylenediamine glycerol (1:1) were analyzed by confocal
laser microscopy (Zeiss dual laser confocal microscope model 1510).
Monolayers were processed for electron microscopy and imaged as
previously described (
33). For immunogold labeling,
filter-grown
confluent T84 monolayers were rinsed in HBSS and fixed
with 3.7%
paraformaldehyde-HBSS (PFA) for 10 min. Filters were
progressively
infiltrated with gelatin at 37°C to a final
concentration of 10%.
The gelatin was solidified on ice, and small
pieces were cut from
the filter, infiltrated with 2.1 M sucrose put on
a stub, and
frozen in liquid nitrogen, and ultrathin cryosections were
collected
on grids. The grids were subsequently incubated for 1 h
each at
room temperature with purified caveolin-1 polyclonal antibodies
(1:20) and protein A-coupled 10-nm gold particles. The grids were
rinsed, fixed in 4% PFA, and incubated with polyclonal antibody
to
occludin (1:400) for 1 h followed by protein A-coupled 15-nm
gold
particles for 1 h at room temperature. The grids were rinsed
and
incubated for 5 min on ice in 0.3% uranyl acetate-1.8%
methylcellulose
in tridistilled water (5 min at 4°C). Excess fluid
was removed,
and grids were air dried and analyzed. Controls included
omission
of primary
antibodies.
| |
RESULTS |
C. difficile toxins enhance paracellular permeability
in epithelial monolayers.
We utilized previously characterized
reference toxins. TcdA and TcdB, for our studies (24, 25,
51). These toxins induced a profound drop in transepithelial
resistance within 2 h (Fig. 1). Dilution
studies revealed a maximal fall in transepithelial resistance using 240 ng of TcdA per ml and 80 ng of TcdB per ml, suggesting that T84 cells
are more sensitive to TcdB than to TcdA. The fall in transepithelial
resistance was observed after application of TcdA or TcdB to either the
apical or basolateral compartments. Time course experiments for the
drop in transepithelial resistance were similar irrespective of apical
or basolateral application of TcdAB. To determine if the drop in
transepithelial resistance in toxin-treated monolayers (240 ng of TcdA
per ml and 80 ng of TcdB per ml for 2 h) represented enhanced
paracellular permeability, we undertook flux assays using radiolabeled
mannitol. The cumulative transmonolayer flux of
[3H]mannitol was significantly enhanced by both TcdA and
TcdB (Fig. 1B), suggesting increased paracellular permeability. As
mentioned above, we noted greater sensitivity of T84 cells to TcdB than to TcdA. These findings are in keeping with previous reports
illustrating the influence of C. difficile toxins in other
cell types (1, 6, 39). In particular, these studies
documented an enhanced sensitivity of native intestinal epithelium to
C. difficile toxin B compared to toxin A (~10 fold) and
that TcdB-10463 is enzymatically more potent than TcdA-10463.
View larger version (11K):
[in this window]
[in a new window]
|
FIG. 1.
C. difficile toxins enhance paracellular
permeability of T84 epithelial monolayers. T84 monolayers were
incubated with C. difficile toxin A-10463 (TcdA, 240 ng/ml)
or B-10463 (TcdB, 80 ng/ml). (A) Time course experiments demonstrated a
maximal fall in the transepithelial resistance in ~2 h. (B) The
cumulative transmonolayer flux of radiolabled mannitol was measured
after 60 min of TcdAB exposure. A markedly enhanced flux of mannitol
was observed in monolayers incubated with Tcd toxins (B). Analogous to
the resistance results, TcdB was more potent than TcdA in enhancing
monolayer flux.
|
|
F-actin organization in both the apical and basal poles of
epithelial cells is influenced by the C. difficile
toxins.
Given that TcdAB monoglucosylate and inactivate the actin
regulating Rho proteins, we determined F-actin organization in T84 epithelial cells incubated with these toxins. Disruption of F-actin architecture was observed in parallel with the TcdAB-induced increase in paracellular permeability. Rhodamine phalloidin was utilized to
highlight the F-actin organization. Representative en face confocal
images of epithelial cells exposed to TcdB are shown in Fig.
2. While control epithelial monolayers
had organized F-actin in the apical brush border/perijunctional actin
ring and basal stress fibers, the TcdB monolayers exhibited
disorganization and disruption of normal F-actin architecture. As can
be seen in Fig. 2, both apical and basal F-actin structures were
markedly altered by TcdB treatment. The earliest change in F-actin
organization was observed within 1 h of TcdB incubation (80 ng of
TcdB per ml). Such alterations were paralleled by a fall in
transepithelial resistance. TcdA induced analogous effects on F-actin
organization (data not shown).
View larger version (149K):
[in this window]
[in a new window]
|
FIG. 2.
C. difficile toxins influence F-actin
architecture in the apical and basal poles of T84 intestinal epithelial
cells. F-actin distribution in control (serum-free medium) (top panels)
or TcdB (bottom panels)-exposed monolayers was determined 2 h
after toxin incubation. Confocal microscopic localization of F-actin in
en face optical sections reveals a normal F-actin distribution in the
apical membrane and as perijunctional F-actin rings (top left).
Prominent stress fibers are observed in the base of cells (top right).
Incubation with this toxin induced disruption and disorganization of
F-actin in both the apical (bottom left) and basal (bottom right) poles
of T84 cells. Note the loss of apical perijunction F-actin rings and
basal stress fibers. Representative data from six individual
experiments are shown.
|
|
Disassembly of tight junctions by the C. difficile
toxins.
Since TcdA and TcdB toxins enhanced paracellular
permeability and induced disruption of apical F-actin, we determined
the effect of these toxins on distribution of TJ and adherens junction (AJ) proteins. TJ proteins ZO-1, ZO-2, occludin, and the AJ protein E-cadherin in control (medium only) and Tcd-exposed monolayers were
immunolocalized by confocal microscopy (Fig.
3). In control monolayers, the TJ and AJ
proteins immunolocalized as continuous rings. Following TcdB exposure,
the TJ proteins were displaced from the lateral membrane of TJs.
However, we observed no change in E-cadherin distribution. Analogous
effects were seen with TcdA (data not shown). Redistribution of TJ
proteins occurred in parallel with disorganization of F-actin and a
fall in transepithelial resistance. Western blot analysis of whole-cell
lysates from control and Tcd-incubated monolayers, however, did not
show any difference in the total cellular concentrations of TJ
proteins, suggesting that these proteins were not degraded (data not
shown).
View larger version (99K):
[in this window]
[in a new window]
|
FIG. 3.
Organization of tight junction structural proteins is
influenced by C. difficile toxins. TJ proteins (ZO-1, ZO-2,
and occludin) and AJ protein (E-cadherin) in control (medium only) or
TcdB-exposed (2 h) monolayers were localized by immunofluorescence
labeling and confocal microscopy. En face images in the apical region
of epithelial cells reveal a normal "chicken wire" pattern of
staining for ZO-1 (A), ZO-2 (C), and occludin (E) at TJs of control
monolayers. TcdB exposure induced the displacement of ZO-1 (B), ZO-2
(D), and occludin (F) from the lateral membrane. However, distribution
of E-cadherin in control monolayers (G) was indistinguishable from that
in TcdB-exposed monolayers (H). Representative data from six individual
experiments are shown.
|
|
TcdB modulates the association of the TJ protein ZO-1 with the
actin cytoskeleton.
Since the actin cytoskeleton is central in
regulation of TJ function and is itself regulated by Rho proteins, we
determined the influence of TcdB on association of a TJ protein. ZO-1,
with actin by coprecipitation experiments (17, 28, 29,
31). Actin immunoprecipiated from control (medium only) and
TcdB-exposed monolayers was Western blotted with antibodies to the TJ
cytoplasmic plaque protein ZO-1 and actin (Fig.
4). Only trace amounts of ZO-1 were
detected in actin immunoprecipitates of toxin-treated cells. Actin was
detectable in ZO-1 immunoprecipitates from toxin-treated cells,
although at much reduced levels compared to those in untreated controls. Taken together, these results suggest that incubation of T84
monolayers with TcdB decreases the coprecipitation of ZO-1 with actin.
View larger version (44K):
[in this window]
[in a new window]
|
FIG. 4.
Decreased coprecipitation of ZO-1 and actin following
C. difficile toxin exposure. Actin (A) and ZO-1 (B) were
immunoprecipitated (Ip) from control (lanes C) and TcdB (80 ng/ml for
2 h)-exposed (lanes TcdB) monolayers as detailed in Materials and
Methods. Immunoprecipitated proteins were Western blotted with
antibodies to ZO-1 or actin. Note the diminished ZO-1 level in actin
immunoprecipitates following inactivation of Rho proteins with TcdB
(arrow). Conversely, ZO-1 immunoprecipitates were probed with
antibodies to ZO-1 and actin. Note the decreased intensity actin band
in panel B (arrow). The band representing immunoglobulin G is marked as
such (IgG). Representative data from three individual experiments are
shown.
|
|
The association of TJ proteins with membrane rafts (DIGs) is
modulated by TcdB.
Biochemical properties of TJ-associated
proteins such as occludin and ZO-1 include TX-100 insolubility, which
has been attributed to either association of protein complexes with the
cytoskeleton or protein oligomerization (54).
Alternatively, TX-100 insolubility has been shown to be a property of
proteins that partition to membrane microdomains also referred to as
"rafts" or DIGs (2, 5, 18, 27). Utilizing differential
detergent extraction and isopycnic sucrose density gradients, we
recently documented a major pool of TJ proteins (HO and ZO-1) in
raft-like membrane microdomains or DIGs (36). Since the
Tcd toxins influenced paracellular permeability and TJ disassembly, we
examined the effects of the above C. difficile toxins on
association of TJ proteins with membrane rafts (Fig.
5 and 6).
Control (medium only) and TcdB-exposed (80 ng · ml
1
for 2 h) epithelial monolayers were scraped into buffer containing 1% TX-100, and low-density TX-100 insoluble complexes physically akin
to membrane rafts were isolated by floatation on linear 5 to 30%
(wt/wt) sucrose density gradients. In agreement with other reports
(5, 41), light density fractions containing
TX-100-insoluble complexes (density of 1.08 g/cm3) with
light-scattering properties and enrichment in alkaline phosphatase
activity were isolated (Fig. 5). Alkaline phosphatase has been used as
a marker of plasma membranes and due, to its glycosylphosphatidylinositol linkage, resides in membrane microdomains with characteristics of membrane rafts or DIGs. As can be seen in Fig.
5, the light-scattering and alkaline phosphatase profiles were not
significantly influenced by preexposure of epithelial cells to the TcdB
toxin, suggesting that the toxin did not grossly alter the overall DIG
characteristics. However, as shown in Fig. 6, disassembly of TJs
induced by TcdB incubation markedly influenced the recovery of ZO-1 and
HO (72 to 79 kDa) in the DIG fractions. In particular, HO was
significantly reduced and ZO-1 was displaced from the low-density
fractions to the bottom of the gradient (high-density fractions) (Fig.
6). Furthermore the above toxin-induced effects were TJ specific since
TcdB treatment did not influence the partitioning of E-cadherin, a
major component of the subjacent AJ. Analogous studies were performed
to examine the influence of TcdA, and similar results were obtained
(data not shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 5.
Influence of TcdB on association of TJ proteins with
"raft like" membrane microdomains: Control (medium only) (C) and
TcdB-exposed epithelial monolayers (90 cm2/condition) were
isolated at 4°C in the presence of 1% TX-100 and separated in a
linear 5 to 30% (weight/weight) sucrose gradient, and 0.5-ml fractions
were analyzed. The profiles of light scattering at an optical density
of 600 nm (OD 600 nm) and membrane alkaline phosphatase activity of the
gradient fractions are shown. TX-100-insoluble complexes in 22% ± 2%
sucrose (1.08 g/cm3) from control monolayers of cells
exhibit peak light scattering at 600 nm and have prominent alkaline
phosphatase activity. Significant changes in these profiles were not
observed following incubation with TcdB for 2 h. Representative
data from three individual experiments are shown.
|
|
View larger version (72K):
[in this window]
[in a new window]
|
FIG. 6.
C. difficile toxin B influences the
distribution of TJ proteins occludin and ZO-1 in TX-100-insoluble
raft-like membrane microdomains. Sucrose gradient fractions from
epithelial monolayers described in the legend to Fig. 5 were analyzed
by immunoblotting for the TJ proteins occludin and ZO-1. Lanes I, II,
and III represent fractions taken from the top of the gradient (<20%
sucrose, one lane shown), peak light-scattering fractions (~22%
sucrose containing DIG fractions, two lanes shown), and representative
fractions from the bottom of the gradients (>30% sucrose, four lanes
shown), respectively. For occludin distribution; multiple bands ranging
from 65 to 79 kDa were observed. While the low-molecular-mass species
(~65 to 71 kDa) was distributed in both the low- and high-density
sucrose fractions, the high-molecular-mass species (~72 to 79 kDa
[arrow]) was observed in the low-density (~22 to 24%)
TX-100-insoluble sucrose fractions. Preexposure of epithelial
monolayers to TcdB and disassembly of TJs resulted in a decrease in
high-molecular-mass occludin in the light-scattering fractions. For
ZO-1 distribution, Western blots of gradient fractions from control
epithelial monolayers revealed a major pool of recoverable ZO-1 in
raft-containing low-density fractions (panel II, arrow) compared to the
high-density fractions in the bottom of the gradient. Following
exposure to TcdB (80 ng/ml for 2 h), ZO-1 redistributed
predominantly to the high-density sucrose fractions (panel III, arrow).
A broad nonspecific band at ~150 to 170 kDa that does not represent
ZO-1 staining was observed with the Zymed polyclonal antibody raised to
a ZO-1 fusion protein. E-cadherin was distributed in both the
low-density (panel II) and high-density (panel III) fractions, a
pattern that was not influenced by the Tcd toxin. The above results are
representative results from four individual experiments. OD 600nm,
optical density at 600 nm.
|
|
Effects of Tcd on the ultrastructure of TJs.
Ultrastructural
studies were undertaken to analyze influence of the C. difficile toxins on TJs. In agreement with our immunofluorescence results, treatment of T84 monolayers with TcdAB resulted in alteration of TJ ultrastructure (Fig. 7).
Specifically, the peak Tcd-induced increase in paracellular
permeability at a 2-h time point was accompanied by an initial loss of
TJ membrane fusions ("kisses") and subsequently by complete loss of
TJ architecture.
View larger version (63K):
[in this window]
[in a new window]
|
FIG. 7.
Modulation of TJ structure by TcdB. Electron microscopic
analysis of epithelial monolayers incubated in the presence and absence
of TcdB is shown. (A) The representative micrographs illustrate an
intact TJ in control cells (I) and a disrupted TJ with loss of membrane
kisses following TcdB exposure (II). (B) Ultrastructural distribution
of occludin and caveolin-1 following TcdB exposure. The ultrastructural
distribution of occludin and caveolin 1 was determined by immunogold
labeling and electron microscopy. The distribution of occludin and
caveolin-1 is shown by the 15- and 10-nm gold particles, respectively.
Panel I shows a normal distribution of occludin and caveolin-1 in the
TJ lateral membrane (arrow). Following incubation with the TcdB toxin,
these proteins are internalized from the lateral membrane of the TJ
(panel II). Colocalization of these proteins inside the cells is
observed along membranous structures (arrows). This is further
highlighted in the inset (right lower corner). Bar, 200 nm.
|
|
Since a subpopulation of DIGs contain a transmembrane scaffolding
protein, caveolin (reviewed in reference
18 and by R.
G. Parton and K. Simons, Comment, Science
269:1398-1399.
1995), that ocally colocalizes with occludin (
36), we
examined
the influence of TcdB on the occludin-caveolin association in
TJs by immunogold labeling and electron microscopy (Fig.
7, panels
II).
As can be seen, TcdB-induced TJ disassembly was associated
with
internalization of occludin (larger [15-nm] gold particles)
from the
lateral membrane, consistent with the immunofluorescence
results.
Interestingly, occludin is seen in association with membranous
structures containing caveolin-1 (small [10-nm] gold particles).
These membranous structures are reminiscent of caveolin-containing
DIGs
(
45). Other areas were also identified where complete
internalization
of occludin was observed. Internalization of occludin
from the
lateral membrane in membranous structures in this manner could
possibly implicate DIGs as a mechanism by which occludin could
be
recycled to the TJ membrane during the assembly of
TJs.
| |
DISCUSSION |
C. difficile TcdA and TcdB are UDP-glucosyltransferases
that inactivate the Rho family of small GTPases by their ability to monoglucosylate these proteins. These toxins have a profound influence on the epithelial lining of the intestine and are associated with the
common disorder pseudomembranous colitis. In this condition, colonic
colonization by C. difficile results in profuse diarrhea that correlates with the presence of yellow plaques or pseudomembranes on the colonic mucosal surface. Histologically, there is severe acute
inflammation with crypt destruction and abundant epithelial damage. The
composition of pseudomembranes consists of polymorphonuclear leukocytes, fibrin, and cellular debris released from the affected mucosa. In this report, we document TcdAB-induced disruption of TJ
structure and function that is likely to be an early event in
epithelial damage induced by these toxins. In particular, we demonstrate that C. difficile toxin incubation results in
decreased association of ZO-1 with the actin cytoskeleton and
with TX-100-insoluble membrane microdomains. Such changes are
accompanied by a diminished pool of high-molecular-weight occludin and
internalization of occludin from the lateral TJ membrane.
The purified C. difficile toxins A and B used in our studies
mediate global changes in F-actin architecture in both the apical and
basal poles of T84 epithelial cells. The apical perijunction F-actin
ring affiliates and regulates TJ function (29, 32). Thus,
it is not surprising that disruption of this F-actin pool is associated
with enhanced paracellular permeability. We have previously utilized C3
transferase from Clostridium botulinum to examine Rho
protein function in intestinal epithelial cells. C3 transferase
specifically ADP-ribosylates Rho, thereby influencing Rho effector
coupling. Unlike the C. difficile toxins A and B, C3 does
not modify other members of the Rho family, Rac and Cdc42. In our
system, C3 transferase influences only the apical pool of F-actin in
addition to inducing enhanced paracellular permeability and
redistribution of ZO-1 (34). The results of our studies with the C. difficile and C3 toxins are in agreement with
the results of studies of other cell types documenting a central role of Rho proteins in organizing polarized complexes of F-actin (22, 23). Taken together, these results support the concept that the
Rho family of GTP binding proteins are central in determining the
organization of F-actin and TJs in epithelial cells.
In addition to the prominent reorganization of F-actin, exposure of our
epithelial monolayers to C. difficile toxins results in
disruption of TJs and reduced association of ZO-1 with actin. The
molecular mechanisms that underlie these prominent changes are not
clear. Disorganization of apical F-actin and disruption of TJ function
and structure occur in the same time frame. Such results provide
additional support to the notion that the apical F-actin-TJ link is
vital for regulation of paracellular permeability in epithelial cells.
Recent studies suggest organization of HO and ZO-1 in membrane
raft-like structures, also referred to as DIGs, which are central to TJ
function (36). Features of these microdomains include TX-100 insolubility, a buoyant density of ~1.08 g/cm3,
and enrichment in sphingolipids and cholesterol. Such DIG-like membrane
microdomains appear to be central in many signaling pathways that
originate from the cell surface (2, 27, 41). These compartments are enriched in a diverse array of signal transduction proteins. Thus, given the dynamic regulation of TJs, it is not surprising that its structural components are enriched in raft-like membrane microdomains. We had hypothesized that TJs contain numerous DIG-like membrane microdomains that constitute the sealing elements of
TJs. Association of DIG proteins with the underlying actin cytoskeleton
could act to organize TJ DIGs in beaded, linear assemblies, such as
observed in freeze fracture electron microscopy (3, 16, 42,
46). The diminished association of occludin and ZO-1 with
DIG-like membrane microdomains after exposure to TcdB supports a role
of the Rho family of proteins in maintaining an affiliation of TJ
proteins with such membrane microdomains.
In summary, from these data and those of others, it can be inferred
that TcdA and TcdB mediate their effects on TJ structure and function
via inactivation of Rho proteins. We demonstrate that exposure of
epithelial monolayers to TcdA and TcdB results in disruption of both
TJs and the actin cytoskeleton in parallel with a reduction in the
association of ZO-1 with actin. It is clear that the apical aspect of
the actin cytoskeleton is central in the regulation of TJ structure and
function (28, 31, 33). Furthermore, the apical pool of
F-actin is regulated by Rho proteins, as has been shown for Rho using
C3 transferase (34). Since it is well established that
TcdA and TcdB also specifically inactivate Rho protein family members
by monoglucosylation (24, 25, 50), it is reasonable to
assume that the effects of the toxin on apical actin structure and TJ
morphology may result from Rho inactivation. However, since TcdAB also
inactivate other Rho-related proteins, the contribution of these
additional Rho family members to TJ structure and function is less
clear. A better understanding of molecular mechanisms of TcdAB will
provide insights into the role of small GTP binding proteins in barrier
function and the pathophysiology of pseudomembranous colitis.
| |
ACKNOWLEDGMENTS |
We thank C. Foley for his expert technical assistance.
These studies were supported by National Institute of Health grants
DK02130, DK53202, DK35932, DK55679, HL54229, and HL60540 and by
Deutsche Forschungsgemeinschaft grants DFG Ei206/8-2 and g-2
to C.V.E.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology and Laboratory Medicine, Emory University, WMRB 2335, 1639 Pierce Dr., Atlanta, GA 30322. Phone: (404) 727-8543. Fax: (404) 727-3321. E-mail: anusrat{at}emory.edu.
Editor:
J. T. Barbieri
| |
REFERENCES |
| 1.
|
Aktories, K.
1997.
Bacterial toxins that target Rho proteins.
J. Clin. Investig.
99:827-829[Medline].
|
| 2.
|
Anderson, R. G.
1993.
Caveolae: where incoming and outgoing messengers meet.
Proc. Natl. Acad. Sci. USA.
90:10909-10913[Abstract/Free Full Text].
|
| 3.
|
Balda, M. S.,
M. B. Fallon,
C. M. Van Itallie, and J. M. Anderson.
1992.
Structure, regulation, and pathophysiology of tight junctions in the gastrointestinal tract.
Yale J. Biol. Med.
65:725-735[Medline], 737-740.
|
| 4.
|
Brown, D. A., and E. London.
1997.
Structure of detergent-resistant membrane domains: does phase separation occur in biological membranes?
Biochem. Biophys. Res. Commun.
240:1-7[CrossRef][Medline].
|
| 5.
|
Brown, D. A., and J. K. Rose.
1992.
Sorting of GPI-anchored proteins to glycolipid-enriched membrane subdomains during transport to the apical cell surface.
Cell
68:533-544[CrossRef][Medline].
|
| 6.
|
Chaves-Olarte, E.,
M. Weidmann,
C. Eichel-Streiber, and M. Thelestam.
1997.
Toxins A and B from Clostridium difficile differ with respect to enzymatic potencies, cellular substrate specificities, and surface binding to cultured cells.
J. Clin. Investig.
100:1734-1741[Medline].
|
| 7.
|
Chun, M.,
U. K. Liyanage,
M. P. Lisanti, and H. F. Lodish.
1994.
Signal transduction of a G protein-coupled receptor in caveolae: colocalization of endothelin and its receptor with caveolin.
Proc. Natl. Acad. Sci. USA.
91:11728-11732[Abstract/Free Full Text].
|
| 8.
|
Ciesla, W. P., Jr., and D. A. Bobak.
1998.
Clostridium difficile toxins A and B are cation-dependent UDP-glucose hydrolases with differing catalytic activities.
J. Biol. Chem.
273:16021-16026[Abstract/Free Full Text].
|
| 9.
|
Denker, B. M.,
C. Saha,
S. Khawaja, and S. K. Nigam.
1996.
Involvement of a heterotrimeric G protein alpha subunit in tight junction biogenesis.
J. Biol. Chem.
271:25750-25753[Abstract/Free Full Text].
|
| 10.
|
Dillon, S. T.,
E. J. Rubin,
M. Yakubovich,
C. Pothoulakis,
J. T. LaMont,
L. A. Feig, and R. J. Gilbert.
1995.
Involvement of Ras-related Rho proteins in the mechanisms of action of Clostridium difficile toxin A and toxin B.
Infect. Immun.
63:1421-1426[Abstract].
|
| 11.
|
Fanning, A. S.,
B. J. Jameson,
L. A. Jesaitis, and J. M. Anderson.
1998.
The tight junction protein ZO-1 establishes a link between the transmembrane protein occludin and the actin cytoskeleton.
J. Biol. Chem.
273:29745-29753[Abstract/Free Full Text].
|
| 12.
|
Friedrichson, T., and T. V. Kurzchalia.
1998.
Microdomains of GPI-anchored proteins in living cells revealed by crosslinking.
Nature
394:802-805[CrossRef][Medline].
|
| 13.
|
Furuse, M.,
T. Hirase,
M. Itoh,
A. Nagafuchi,
S. Yonemura,
S. Tsukita, and S. Tsukita.
1993.
Occludin: a novel integral membrane protein localizing at tight junctions.
J. Cell Biol.
123:1777-1788[Abstract/Free Full Text].
|
| 14.
|
Furuse, M.,
M. Itoh,
T. Hirase,
A. Nagafuchi,
S. Yonemura,
S. Tsukita, and S. Tsukita.
1994.
Direct association of occludin with ZO-1 and its possible involvement in the localization of occludin at tight junctions.
J. Cell Biol.
127:1617-1626[Abstract/Free Full Text].
|
| 15.
|
Furuse, M.,
H. Sasaki,
K. Fujimoto, and S. Tsukita.
1998.
A single gene product, claudin-1 or -2, reconstitutes tight junction strands and recruits occludin in fibroblasts.
J. Cell Biol.
143:391-401[Abstract/Free Full Text].
|
| 16.
|
Gumbiner, B.
1987.
Structure, biochemistry, and assembly of epithelial tight junctions.
Am. J. Physiol.
87:C749-C758.
|
| 17.
|
Hall, A.
1998.
Rho GTPases and the actin cytoskeleton.
Science
279:509-514[Abstract/Free Full Text].
|
| 18.
|
Harder, T., and K. Simons.
1997.
Caveolae, DIGs, and the dynamics of sphingolipid-cholesterol microdomains.
Curr. Opin. Cell Biol.
9:534-542[CrossRef][Medline].
|
| 19.
|
Hecht, G.,
A. Koutsouris,
C. Pothoulakis,
J. T. LaMont, and J. L. Madara.
1992.
Clostridium difficile toxin B disrupts the barrier function of T84 monolayers.
Gastroenterology
102:416-423[Medline].
|
| 20.
|
Hecht, G.,
C. Pothoulakis,
J. T. Lamont, and J. L. Madara.
1988.
Clostridium difficile toxin A perturbs cytoskeletal structure and tight junction permeability of cultured human intestinal epithelial monolayers.
J. Clin. Investig.
56:1053-1061.
|
| 21.
|
Jesaitis, L. A., and D. A. Goodenough.
1994.
Molecular characterization and tissue distribution of ZO-2, a tight junction protein homologous to ZO-1 and the Drosophila discs-large tumor suppressor protein.
J. Cell Biol.
124:949-961[Abstract/Free Full Text].
|
| 22.
|
Jou, T. S., and W. J. Nelson.
1998.
Effects of regulated expression of mutant RhoA and Racl small GTPases on the development of epithelial (MDCK) cell polarity.
J. Cell Biol.
142:85-100[Abstract/Free Full Text].
|
| 23.
|
Jou, T. S.,
E. E. Schneeberger, and W. J. Nelson.
1998.
Structural and functional regulation of tight junctions by RhoA and Racl small GTPases.
J. Cell Biol.
142:101-115[Abstract/Free Full Text].
|
| 24.
|
Just, I.,
G. Fritz,
K. Aktories,
M. Giry,
M. R. Popoff,
P. Boquet,
S. Hegenbarth, and C. von Eichel-Streiber.
1994.
Clostridium difficile toxin B acts on the GTP-binding protein Rho.
J. Biol. Chem.
269:10706-10712[Abstract/Free Full Text].
|
| 25.
|
Just, I.,
M. Wilm,
J. Selzer,
G. Rex,
C. von Eichel-Streiber,
M. Mann, and K. Aktories.
1995.
The enterotoxin from Clostridium difficile (ToxA) monoglucosylates the Rho proteins.
J. Biol. Chem.
270:13932-13936[Abstract/Free Full Text].
|
| 26.
|
Kaoutzani, P.,
C. A. Parkos,
C. Delp-Archer, and J. L. Madara.
1993.
Isolation of plasma membrane fractions from the intestinal epithelial model T84.
Am. J. Physiol.
264:C1327-C1335[Abstract/Free Full Text].
|
| 27.
|
Lisanti, M. P.,
P. E. Scherer,
J. Vidugiriene,
Z. Tang,
A. Hermanowski-Vosatka,
Y. H. Tu,
R. F. Cook, and M. Sargiacomo.
1994.
Characterization of caveolin-rich membrane domains isolated from an endothelial-rich source: implications for human disease.
J. Cell Biol.
126:111-126[Abstract/Free Full Text].
|
| 28.
|
Madara, J. L.
1987.
Intestinal absorptive cell tight junctions are linked to cytoskeleton.
Am. J. Physiol.
253:C171-C175[Abstract/Free Full Text].
|
| 29.
|
Madara, J. L.
1988.
Tight junction dynamics: is paracellular transport regulated?
Cell
53:497-498[CrossRef][Medline].
|
| 30.
|
Madara, J. L.,
S. P. Colgan,
A. Nusrat,
C. Delp, and C. A. Parkos.
1992.
A simple approach to measurement of electrical parameters of cultured epithelial monolayers: use in assessing neutrophil epithelial interactions.
J. Tissue Culture Methods
14:209-216.
|
| 31.
|
Madara, J. L.,
R. Moore, and S. Carlson.
1987.
Alteration of intestinal tight junction structure and permeability by cytoskeletal contraction.
Am. J. Physiol.
253:C854-C861[Abstract/Free Full Text].
|
| 32.
|
Madara, J. L.,
J. Stafford,
D. Barenberg, and S. Carlson.
1988.
Functional coupling of tight junctions and microfilaments in T84 monolayers.
Am. J. Physiol.
254:G416-G423[Abstract/Free Full Text].
|
| 33.
|
Madara, J. L.,
J. Stafford,
K. Dharmsathaphorn, and S. Carlson.
1987.
Structural analysis of a human intestinal epithelial cell line.
Gastroenterology
92:1133-1145[Medline].
|
| 34.
|
Nusrat, A.,
M. Giry,
J. R. Turner,
S. P. Colgan,
C. A. Parkos,
D. Carnes,
E. Lemichez,
P. Boquet, and J. L. Madara.
1995.
Rho protein regulates tight junctions and perijunctional actin organization in polarized epithelia.
Proc. Nat. Acad. Sci. USA.
92:10629-10633[Abstract/Free Full Text].
|
| 35.
|
Nusrat, A.,
C. A. Parkos,
A. E. Bacarra,
P. J. Godowski,
C. Delp-Archer,
E. M. Rosen, and J. L. Madara.
1994.
Hepatocyte growth factor/scatter factor effects on epithelia. Regulation of intercellular junctions in transformed and nontransformed cell lines, basolateral polarization of c-met receptor in transformed and natural intestinal epithelia, and induction of rapid wound repair in a transformed model epithelium.
J. Clin. Investig.
93:2056-2065.
|
| 36.
|
Nusrat, A.,
C. A. Parkos,
P. Verkade,
C. S. Foley,
T. W. Liang,
W. Innis-Whitehouse,
K. K. Eastburn, and J. L. Madara.
2000.
Tight junctions are membrane microdomains.
J. Cell Sci.
113:1771-1781[Abstract].
|
| 37.
|
Parkos, C. A.,
S. P. Colgan,
C. Delp,
M. A. Arnaout, and J. L. Madara.
1992.
Neutrophil migration across a cultured epithelial monolayer elicits a biphasic resistance response representing sequential effects on transcellular and paracellular pathways.
J. Cell Biol.
117:757-764[Abstract/Free Full Text].
|
| 38.
|
Parkos, C. A.,
C. Delp,
M. A. Arnaout, and J. L. Madara.
1991.
Neutrophil migration across a cultured intestinal epithelium: dependence on a CD11b/CD18-mediated event and enhanced efficiency in the physiologic direction.
J. Clin. Investig.
88:1605-1612.
|
| 39.
|
Riegler, M.,
R. Sedivy,
C. Pothoulakis,
G. Hamilton,
J. Zacherl,
G. Bischof,
E. Cosentini,
W. Feil,
R. Schiessel,
J. T. LaMont, et al.
1995.
Clostridium difficile toxin B is more potent than toxin A in damaging human colonic epithelium in vitro.
J. Clin. Investig.
95:2004-2011.
|
| 40.
|
Saitou, M.,
Y. Ando-Akatsuka,
M. Itoh,
M. Furuse,
J. Inazawa,
K. Fujimoto, and S. Tsukita.
1997.
Mammalian occludin in epithelial cells: its expression and subcellular distribution.
Eur. J. Cell Biol.
73:222-331[Medline].
|
| 41.
|
Sargiacomo, M.,
M. Sudol,
Z. Tang, and M. P. Lisanti.
1993.
Signal transducing molecules and glycosyl-phosphatidylinositol-linked proteins form a caveolin-rich insoluble complex in MDCK cells.
J. Cell Biol.
122:789-807[Abstract/Free Full Text].
|
| 42.
|
Schneeberger, E. E., and R. D. Lynch.
1992.
Structure, function, and regulation of cellular tight junctions.
Am. J. Physiol.
262:L647-L661[Abstract/Free Full Text].
|
| 43.
|
Schnitzer, J. E.,
D. P. McIntosh,
A. M. Dvorak,
J. Liu, and P. Oh.
1995.
Separation of caveolae from associated microdomains of GPI-anchored proteins.
Science
269:1435-1439[Abstract/Free Full Text].
|
| 44.
|
Shapiro, M.,
J. Mattews,
G. Hecht,
C. Delp, and M. J. L.
1991.
Stabilization of F-actin prevents cyclic AMP-elicited C1 secretion in T84 cells.
J. Clin. Investig.
87:1903-1909.
|
| 45.
|
Simons, K., and E. Ikonen.
1997.
Functional rafts in cell membranes.
Nature
387:569-572[CrossRef][Medline].
|
| 46.
|
Stevenson, B. R.,
J. M. Anderson, and S. Bullivant.
1988.
The epithelial tight junction: structure, function and preliminary biochemical characterization.
Mol. Cell. Biochem.
83:129-145[Medline].
|
| 47.
|
Stevenson, B. R., and D. A. Goodenough.
1984.
Zonulae occludentes in junctional complex-enriched fractions from mouse liver: preliminary morphological and biochemical characterization.
J. Cell Biol.
98:1209-1221[Abstract/Free Full Text].
|
| 48.
|
Tsukita, S., and M. Furuse.
1999.
Occludin and claudins in tight-junction strands: leading or supporting players?
Trends Cell Biol.
9:268-273[CrossRef][Medline].
|
| 49.
|
Varma, R., and S. Mayor.
1998.
GPI-anchored proteins are organized in submicron domains at the cell surface.
Nature
394:798-801[CrossRef][Medline].
|
| 50.
|
von Eichel-Streiber, C.,
P. Boquet,
M. Sauerborn, and M. Thelestam.
1996.
Large clostridial cytotoxins a family of glycosyltransferases modifying small GTP-binding proteins.
Trends Microbiol.
4:375-382[CrossRef][Medline].
|
| 51.
|
von Eichel-Streiber, C.,
U. Harperath,
D. Bosse, and U. Hadding.
1987.
Purification of two high molecular weight toxins of Clostridium difficile which are antigenically related.
Microb. Pathog.
2:307-318[CrossRef][Medline].
|
| 52.
|
Weber, E.,
G. Berta,
A. Tousson,
P. St John,
M. W. Green,
U. Gopalokrishnan,
T. Jilling,
E. J. Sorscher,
T. S. Elton,
D. R. Abrahamson, et al.
1994.
Expression and polarized targeting of a rab3 isoform in epithelial cells.
J. Cell Biol.
125:583-594[Abstract/Free Full Text].
|
| 53.
|
Wolf, A. A.,
M. G. Jobling,
S. Wimer-Mackin,
M. Ferguson-Maltzman,
J. L. Madara,
R. K. Holmes, and W. I. Lencer.
1998.
Ganglioside structure dictates signal transduction by cholera toxin and association with caveolae-like membrane domains in polarized epithelia.
J. Cell Biol.
141:917-927[Abstract/Free Full Text].
|
| 54.
|
Wong, V.
1997.
Phosphorylation of occludin correlates with occludin localization and function at the tight junction.
Am. J. Physiol.
273:C1859-C1867[Abstract/Free Full Text].
|
Infection and Immunity, March 2001, p. 1329-1336, Vol. 69, No. 3
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.3.1329-1336.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Anderson, J. M., Van Itallie, C. M.
(2009). Physiology and Function of the Tight Junction. Cold Spring Harb. Perspect. Biol.
1: a002584-a002584
[Abstract]
[Full Text]
-
Liu, L., Guo, X., Rao, J. N., Zou, T., Xiao, L., Yu, T., Timmons, J. A., Turner, D. J., Wang, J.-Y.
(2009). Polyamines regulate E-cadherin transcription through c-Myc modulating intestinal epithelial barrier function. Am. J. Physiol. Cell Physiol.
296: C801-C810
[Abstract]
[Full Text]
-
Li, N., Neu, J.
(2009). Glutamine Deprivation Alters Intestinal Tight Junctions via a PI3-K/Akt Mediated Pathway in Caco-2 Cells. J. Nutr.
139: 710-714
[Abstract]
[Full Text]
-
Brady, D. C., Alan, J. K., Madigan, J. P., Fanning, A. S., Cox, A. D.
(2009). The Transforming Rho Family GTPase Wrch-1 Disrupts Epithelial Cell Tight Junctions and Epithelial Morphogenesis. Mol. Cell. Biol.
29: 1035-1049
[Abstract]
[Full Text]
-
Kokkotou, E, Espinoza, D O, Torres, D, Karagiannides, I, Kosteletos, S, Savidge, T, O'Brien, M, Pothoulakis, C
(2009). Melanin-concentrating hormone (MCH) modulates C difficile toxin A-mediated enteritis in mice. Gut
58: 34-40
[Abstract]
[Full Text]
-
Leve, F., de Souza, W., Morgado-Diaz, J. A.
(2008). A Cross-Link between Protein Kinase A and Rho-Family GTPases Signaling Mediates Cell-Cell Adhesion and Actin Cytoskeleton Organization in Epithelial Cancer Cells. J. Pharmacol. Exp. Ther.
327: 777-788
[Abstract]
[Full Text]
-
Lee, D. B. N., Jamgotchian, N., Allen, S. G., Abeles, M. B., Ward, H. J.
(2008). A lipid-protein hybrid model for tight junction. Am. J. Physiol. Renal Physiol.
295: F1601-F1612
[Abstract]
[Full Text]
-
Casselli, T., Lynch, T., Southward, C. M., Jones, B. W., DeVinney, R.
(2008). Vibrio parahaemolyticus Inhibition of Rho Family GTPase Activation Requires a Functional Chromosome I Type III Secretion System. Infect. Immun.
76: 2202-2211
[Abstract]
[Full Text]
-
Moser, L. A., Carter, M., Schultz-Cherry, S.
(2007). Astrovirus Increases Epithelial Barrier Permeability Independently of Viral Replication. J. Virol.
81: 11937-11945
[Abstract]
[Full Text]
-
Beau, I., Cotte-Laffitte, J., Amsellem, R., Servin, A. L.
(2007). A Protein Kinase A-Dependent Mechanism by Which Rotavirus Affects the Distribution and mRNA Level of the Functional Tight Junction-Associated Protein, Occludin, in Human Differentiated Intestinal Caco-2 Cells. J. Virol.
81: 8579-8586
[Abstract]
[Full Text]
-
Chen, M. L., Ge, Z., Fox, J. G., Schauer, D. B.
(2006). Disruption of Tight Junctions and Induction of Proinflammatory Cytokine Responses in Colonic Epithelial Cells by Campylobacter jejuni. Infect. Immun.
74: 6581-6589
[Abstract]
[Full Text]
-
Shen, L., Black, E. D., Witkowski, E. D., Lencer, W. I., Guerriero, V., Schneeberger, E. E., Turner, J. R.
(2006). Myosin light chain phosphorylation regulates barrier function by remodeling tight junction structure. J. Cell Sci.
119: 2095-2106
[Abstract]
[Full Text]
-
Nguyen, H.-V., Chen, J.-L., Zhong, J., Kim, K.-J., Crandall, E. D., Borok, Z., Chen, Y., Ann, D. K.
(2006). SUMOylation Attenuates Sensitivity toward Hypoxia- or Desferroxamine-Induced Injury by Modulating Adaptive Responses in Salivary Epithelial Cells. Am. J. Pathol.
168: 1452-1463
[Abstract]
[Full Text]
-
Klingberg, T. D., Pedersen, M. H., Cencic, A., Budde, B. B.
(2005). Application of Measurements of Transepithelial Electrical Resistance of Intestinal Epithelial Cell Monolayers To Evaluate Probiotic Activity. Appl. Environ. Microbiol.
71: 7528-7530
[Abstract]
[Full Text]
-
Pechine, S., Janoir, C., Collignon, A.
(2005). Variability of Clostridium difficile Surface Proteins and Specific Serum Antibody Response in Patients with Clostridium difficile-Associated Disease. J. Clin. Microbiol.
43: 5018-5025
[Abstract]
[Full Text]
-
Bruewer, M., Utech, M., Ivanov, A. I., Hopkins, A. M., Parkos, C. A., Nusrat, A.
(2005). Interferon-{gamma} induces internalization of epithelial tight junction proteins via a macropinocytosis-like process. FASEB J.
19: 923-933
[Abstract]
[Full Text]
-
Guo, X., Rao, J. N., Liu, L., Zou, T., Keledjian, K. M., Boneva, D., Marasa, B. S., Wang, J.-Y.
(2005). Polyamines are necessary for synthesis and stability of occludin protein in intestinal epithelial cells. Am. J. Physiol. Gastrointest. Liver Physiol.
288: G1159-G1169
[Abstract]
[Full Text]
-
Voth, D. E., Ballard, J. D.
(2005). Clostridium difficile Toxins: Mechanism of Action and Role in Disease. Clin. Microbiol. Rev.
18: 247-263
[Abstract]
[Full Text]
-
Lynch, T., Livingstone, S., Buenaventura, E., Lutter, E., Fedwick, J., Buret, A. G., Graham, D., DeVinney, R.
(2005). Vibrio parahaemolyticus Disruption of Epithelial Cell Tight Junctions Occurs Independently of Toxin Production. Infect. Immun.
73: 1275-1283
[Abstract]
[Full Text]
-
Solomon, K., Webb, J., Ali, N., Robins, R. A., Mahida, Y. R.
(2005). Monocytes Are Highly Sensitive to Clostridium difficile Toxin A-Induced Apoptotic and Nonapoptotic Cell Death. Infect. Immun.
73: 1625-1634
[Abstract]
[Full Text]
-
Go, M., Kojima, T., Takano, K.-i., Murata, M., Ichimiya, S., Tsubota, H., Himi, T., Sawada, N.
(2004). Expression and Function of Tight Junctions in the Crypt Epithelium of Human Palatine Tonsils. J. Histochem. Cytochem.
52: 1627-1638
[Abstract]
[Full Text]
-
Li, N., Lewis, P., Samuelson, D., Liboni, K., Neu, J.
(2004). Glutamine regulates Caco-2 cell tight junction proteins. Am. J. Physiol. Gastrointest. Liver Physiol.
287: G726-G733
[Abstract]
[Full Text]
-
Bruewer, M., Hopkins, A. M., Hobert, M. E., Nusrat, A., Madara, J. L.
(2004). RhoA, Rac1, and Cdc42 exert distinct effects on epithelial barrier via selective structural and biochemical modulation of junctional proteins and F-actin. Am. J. Physiol. Cell Physiol.
287: C327-C335
[Abstract]
[Full Text]
-
Ivanov, A. I., McCall, I. C., Parkos, C. A., Nusrat, A.
(2004). Role for Actin Filament Turnover and a Myosin II Motor in Cytoskeleton-driven Disassembly of the Epithelial Apical Junctional Complex. Mol. Biol. Cell
15: 2639-2651
[Abstract]
[Full Text]
-
Ivanov, A. I., Nusrat, A., Parkos, C. A.
(2004). Endocytosis of Epithelial Apical Junctional Proteins by a Clathrin-mediated Pathway into a Unique Storage Compartment. Mol. Biol. Cell
15: 176-188
[Abstract]
[Full Text]
-
Bruewer, M., Luegering, A., Kucharzik, T., Parkos, C. A., Madara, J. L., Hopkins, A. M., Nusrat, A.
(2003). Proinflammatory Cytokines Disrupt Epithelial Barrier Function by Apoptosis-Independent Mechanisms. J. Immunol.
171: 6164-6172
[Abstract]
[Full Text]
-
Kansagra, K., Stoll, B., Rognerud, C., Niinikoski, H., Ou, C.-N., Harvey, R., Burrin, D.
(2003). Total parenteral nutrition adversely affects gut barrier function in neonatal piglets. Am. J. Physiol. Gastrointest. Liver Physiol.
285: G1162-G1170
[Abstract]
[Full Text]
-
Chin, A. C., Vergnolle, N., MacNaughton, W. K., Wallace, J. L., Hollenberg, M. D., Buret, A. G.
(2003). Proteinase-activated receptor 1 activation induces epithelial apoptosis and increases intestinal permeability. Proc. Natl. Acad. Sci. USA
100: 11104-11109
[Abstract]
[Full Text]
-
Yoo, J., Nichols, A., Mammen, J., Calvo, I., Song, J. C., Worrell, R. T., Matlin, K., Matthews, J. B.
(2003). Bryostatin-1 enhances barrier function in T84 epithelia through PKC-dependent regulation of tight junction proteins. Am. J. Physiol. Cell Physiol.
285: C300-C309
[Abstract]
[Full Text]
-
Spyres, L. M., Daniel, J., Hensley, A., Qa'Dan, M., Ortiz-Leduc, W., Ballard, J. D.
(2003). Mutational Analysis of the Enzymatic Domain of Clostridium difficile Toxin B Reveals Novel Inhibitors of the Wild-Type Toxin. Infect. Immun.
71: 3294-3301
[Abstract]
[Full Text]
-
Liu, T. S., Musch, M. W., Sugi, K., Walsh-Reitz, M. M., Ropeleski, M. J., Hendrickson, B. A., Pothoulakis, C., Lamont, J. T., Chang, E. B.
(2003). Protective role of HSP72 against Clostridium difficile toxin A-induced intestinal epithelial cell dysfunction. Am. J. Physiol. Cell Physiol.
284: C1073-C1082
[Abstract]
[Full Text]
-
Rubenstein, N. M., Guan, Y., Woo, P. L., Firestone, G. L.
(2003). Glucocorticoid Down-regulation of RhoA Is Required for the Steroid-induced Organization of the Junctional Complex and Tight Junction Formation in Rat Mammary Epithelial Tumor Cells. J. Biol. Chem.
278: 10353-10360
[Abstract]
[Full Text]
-
Berkes, J, Viswanathan, V K, Savkovic, S D, Hecht, G
(2003). Intestinal epithelial responses to enteric pathogens: effects on the tight junction barrier, ion transport, and inflammation. Gut
52: 439-451
[Abstract]
[Full Text]
-
Hopkins, A. M., Walsh, S. V., Verkade, P., Boquet, P., Nusrat, A.
(2003). Constitutive activation of Rho proteins by CNF-1 influences tight junction structure and epithelial barrier function. J. Cell Sci.
116: 725-742
[Abstract]
[Full Text]
-
Tafazoli, F., Magnusson, K.-E., Zheng, L.
(2003). Disruption of Epithelial Barrier Integrity by Salmonella enterica Serovar Typhimurium Requires Geranylgeranylated Proteins. Infect. Immun.
71: 872-881
[Abstract]
[Full Text]
-
Edens, H. A., Levi, B. P., Jaye, D. L., Walsh, S., Reaves, T. A., Turner, J. R., Nusrat, A., Parkos, C. A.
(2002). Neutrophil Transepithelial Migration: Evidence for Sequential, Contact-Dependent Signaling Events and Enhanced Paracellular Permeability Independent of Transjunctional Migration. J. Immunol.
169: 476-486
[Abstract]
[Full Text]
-
Chen, M. L., Pothoulakis, C., LaMont, J. T.
(2002). Protein Kinase C Signaling Regulates ZO-1 Translocation and Increased Paracellular Flux of T84 Colonocytes Exposed to Clostridium difficile Toxin A. J. Biol. Chem.
277: 4247-4254
[Abstract]
[Full Text]
-
Abreu, M. T., Arnold, E. T., Chow, J. Y. C., Barrett, K. E.
(2001). Phosphatidylinositol 3-Kinase-dependent Pathways Oppose Fas-induced Apoptosis and Limit Chloride Secretion in Human Intestinal Epithelial Cells. IMPLICATIONS FOR INFLAMMATORY DIARRHEAL STATES. J. Biol. Chem.
276: 47563-47574
[Abstract]
[Full Text]
Top
Abstract
Introduction
