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Vol. 294, Issue 3, 997-1008, September 2000
Departments of Internal Medicine (Division of Digestive Diseases), Pharmacology, and Molecular Biophysics and Physiology, Rush University Medical Center, Chicago, Illinois
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Abstract |
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 Top
 Abstract
 Introduction
Materials and Methods
Results
Discussion
References
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Loss of gastrointestinal (GI) barrier integrity has been implicated in
a wide range of inflammatory illnesses, including alcoholic cirrhosis.
Using monolayers of Caco-2 (intestinal) cells as a model, we showed
that the ability of ethanol (EtOH) to disrupt intestinal barrier
integrity depends on damage to the microtubule (MT) cytoskeleton,
especially oxidative injury. One drug that prevented both the MT damage
and barrier disruption was
L-N6-1-iminoethyl-lysine, a
selective inhibitor of the inducible form of nitric-oxide synthase
(iNOS). Because of this finding and because overproduction of nitric
oxide (NO) and generation of peroxynitrite (ONOO
) have
been proposed to be responsible for mucosal injury in other GI
disorders, we sought to determine whether NO overproduction and
ONOO formation mediates EtOH-induced MT damage and loss
of intestinal barrier function. To this end, Caco-2 monolayers were
exposed to EtOH or to authentic ONOO or
ONOO generators with or without pretreatment with iNOS
inhibitors or antioxidants. We found that EtOH caused 1) iNOS
activation, 2) NO overproduction, 3) increases in oxidative stress and
superoxide anion production (superoxide dismutase quenchable
fluorescence of dichlorofluorescein), 4) nitration and oxidation of
tubulin (immunoblotting), 5) decreased levels of stable polymerized
tubulin, and 6) increased levels of disassembled tubulin. EtOH also 7) extensively damaged the MT cytoskeleton and 8) disrupted barrier function. Authentic ONOO or ONOO donors had
similar effects. Pretreatment with a selective iNOS inhibitor,
L-N6-1-iminoethyl-lysine, or
with antioxidants (ONOO scavengers urate or
L-cysteine; superoxide anion scavenger superoxide dismutase) attenuated damage due to EtOH or to ONOO
generators. We conclude that EtOH-induced MT damage and intestinal barrier dysfunction require iNOS activation followed by NO
overproduction and ONOO formation. These findings provide
a rationale for the development of novel therapeutic agents for
alcohol-induced GI disorders that inhibit this mechanism.
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Introduction |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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The
gastrointestinal (GI) epithelium is a highly selective barrier that
normally prevents the passage of harmful molecules across the mucosa
and into the circulation (Bode et al., 1987
; Hollander, 1992). An
abnormal GI barrier, in contrast, can allow the penetration of normally
excluded luminal substances (e.g., endotoxin) across the mucosa and can
lead to the initiation and/or perpetuation of inflammatory processes
and mucosal damage. This damage, and the ensuing loss of GI barrier
integrity, has been implicated in a wide range of inflammatory
illnesses, including alcoholic cirrhosis (Bode et al., 1987; Hollander,
1992; Keshavarzian et al., 1994). The underlying difficulty in
managing these inflammatory disorders is due in large part to our
limited understanding of their pathophysiology.
For example, alcohol [ethanol (EtOH)] intake injures the functional
and structural integrity of the intestinal mucosa (Bjorkman and Jessop,
1994) and causes loss of intestinal barrier function (Talbot et al.,
1984; Keshavarzian et al., 1994, 1999). This is thought to be important
in the development of alcoholic cirrhosis (Bode et al., 1987;
Keshavarzian et al., 1999). Little is known, however, as to the
underlying mechanisms. While investigating this mechanism, we showed
(Banan et al., 1998b, 1999a,b,c, 2000), using monolayers of intestinal
cells as a model, that EtOH-induced disruption of barrier integrity
requires damage to and disruption of the microtubule cytoskeleton.
Oxidative damage appeared to be key because microtubules became
oxidized and because several agents, including antioxidants, prevented
these effects of EtOH. One of these drugs was
L-N6-1-iminoethyl-lysine
(L-NIL), a selective inhibitor of inducible nitric-oxide synthase (iNOS). iNOS was further implicated by the observations that EtOH increased iNOS activity and that
L-NIL prevented not only the iNOS up-regulation
but also the EtOH-induced microtubule damage and barrier disruption.
iNOS up-regulation is predicted to lead to NO overproduction (Chen et
al., 1996; Salzman et al., 1996; Unno et al., 1997), and many of the
toxic effects of NO overproduction are mediated by the peroxynitrite
(ONOO), a product of the reaction of NO with
superoxide anions (Radi et al., 1991; Ischiropoulos et al., 1992, 1995;
Rachmilewitz et al., 1995; Haddad et al., 1994; Muijsers et al.,
1997). Indeed, overproduction and uncontrolled generation of
ONOO have been proposed in several recent
studies to be an important factor in tissue damage during inflammation
(Radi et al., 1991; Rachmilewitz et al., 1993, 1995; Ischiropoulos et
al., 1995). Nevertheless, the precise pathogenic mechanism by which
oxidative stress leads to mucosal abnormalities in the intestine,
especially after EtOH insult, is not known. Accordingly, in the present
study, we investigated the possibility that NO overproduction and
ONOO generation cause the oxidative damage to
microtubules that mediates EtOH-induced intestinal barrier dysfunction.
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Materials and Methods |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Cell Culture.
Caco-2 cells (from a human colonic cell line)
were obtained from American Type Culture Collection (Rockville, MD) at
passage 15. Although of colonic origin, these widely studied cells
resemble small intestinal cells in that they have defined apical brush borders, form highly tight junctions, and exhibit a highly organized microtubule network on differentiation (Gilbert et al., 1991). These
cells also express markers of mature enterocytes such as small
intestinal hydrolases (sucrase-isomaltase and alkaline phosphatase) and
nutrient transporters. In addition, these cells resemble small bowel epithelium in having receptors for prostaglandins; growth factors [e.g., epidermal growth factor (EGF), insulin-like
growth factor-I] and insulin; receptors for vasoactive intestinal
peptide and low-density lipoprotein, and transporters such as
dipeptides, fructose, glucose, other hexoses, and vitamin
B12 (Gilbert et al., 1991). Accordingly, Caco-2
cell model provides a suitable in vitro model for our barrier function
studies. Cells were maintained at 37°C in Dulbecco's modified
Eagle's medium in an atmosphere of 5% CO2 and
100% relative humidity. Cells were split at a ratio of 1:6 on reaching
confluency every 6 days and set up in either 6-, 24-, or 48-well plates
for experiments or in T-175 flasks for the maintenance of stocks. Cells
grown for barrier integrity work were split at a ratio of 1:2 and
seeded at a density of 200,000 cells/cm2 into
0.4-µm Biocoat Collagen I Cell Culture Inserts
(0.3-cm2 growth surface; Becton Dickinson
Labware, Bedford, MA), and experiments were performed at least 7 days
postconfluence. The utility, maintenance, and characterization of this
cell line have been previously published (Gilbert et al., 1991).
Experimental Design.
In the first series of experiments, we
evaluated the effect of 30-min exposure of cells to injurious (2.5 and
15%) and noninjurious (1%) concentrations of EtOH (v/v) or vehicle
(isotonic saline/Dulbecco's modified Eagle's medium) on cell
monolayer barrier integrity, iNOS activity, NO production,
ONOO generation (i.e., nitration and
oxidation), oxidative stress, and microtubule disassembly and
instability as described later. The concentrations of EtOH used in the
present investigation are clinically relevant (Dinda et al., 1996;
Bjorkman and Jessop, 1994) and have previously been shown by us to
cause loss of monolayer barrier function without cell death in this
cell line (Banan et al., 1998a,b).
(Alexis Corp., San Diego, CA) or
ONOO donors (Sigma Chemical Co., St. Louis, MO)
to mimic the effects of EtOH on barrier function and on the microtubule
cytoskeleton. Monolayers were incubated with NOS substrate or
NO-related agents (listed here) (Sigma Chemical Co.) and, in selected
experiments, with EtOH or vehicle. Agents and incubation times included
1) an NOS substrate, L-arginine (L-Arg, 3 mM,
48 h), 2) authentic ONOO (0.01-1.0 mM,
see later) or ONOO-generating systems:
1,3-morpholinosydnonymine (SIN-1; 0.1-5 mM), or a combination of
S-nitroso-N-acetyl penicillamine (SNAP; 1 mM)
plus xanthine (X; 1 mM) plus xanthine oxidase (XO; 100 mU/ml). These
doses of agents were determined to be effective in our pilot studies
and in previously published studies (Salzman et al., 1996; Kennedy et
al., 1998, 1999). To promote stability of ONOO
in solution, ONOO (180 mM stock in 0.3 M NaOH;
Alexis Corp. San Diego, CA) was added to the cell culture media to a
final pH 7.6. Aliquots of ONOO and HCl were
added just above the surface of the cell culture solution on the side
of the culture dish immediately followed by a gentle swirl. The
concentration of ONOO in the cell culture media
was monitored by removing a small aliquot and measuring the increase in
absorbance at a wavelength of 302 nm (E302 nm = 1.67 mM1 cm1). Because
ONOO does degrade over time due to its reaction
with water, we normalized ONOO values to that
of an internal ONOO standard incubated under
identical conditions and expressed the results as a percentage. In
preliminary studies, we noted no adverse effects due to the use of pH
of 7.6 on monolayer barrier function, on cell viability, or on the cytoskeleton.
In a third series of experiments, we investigated the effects of
pretreatment with either an isoform-selective NOS inhibitor or with
various antioxidants (listed here) that prevent
ONOO formation or scavenge
ONOO. Outcome measures were, again, cell
oxidative state, barrier function, and microtubule assembly and
stability. We anticipated that these agents would protect monolayers
exposed to EtOH or ONOO. All pretreatment drugs
were left in the incubation media during the subsequent steps: 1) NO
scavengers urate (0.5 mM) or L-cysteine (3 mM) (or, as
control, D-cysteine) preincubated for 30 min before EtOH or
ONOO compounds; 2) a superoxide scavenger,
superoxide dismutase (SOD, 300 U/ml) [or heat-inactivated SOD (iSOD)]
(Ferro et al., 1997) preincubated for 30 min before EtOH or
ONOO compounds; or 3) the selective iNOS
inhibitor
L-N6-1-iminoethyl-lysine
(L-NIL, 1 mM) or the nonselective
NG-nitro-L-arginine
(L-NNA, 1 mM) or
NG-monomethyl-L-arginine
(L-NMMA, 1 mM) (Salzman et al., 1996; Banan et
al., 1999a) 1 h before EtOH. To determine whether the effects of
NOS inhibitors was specific to inhibition of NOS,
L-arginine (L-Arg; 3 mM) was added to
selected assays to reverse the inhibition by NOS inhibitors. Inhibitors
or scavengers were purchased from Sigma Chemical Co.
In a final series of experiments, we investigated the role of tubulin
nitrotyrosination or carbonylation and of tubulin disassembly in
microtubule cytoskeletal instability and epithelial barrier dysfunction. Monomeric and polymerized fractions of tubulin (structural protein of the microtubules) were isolated and then analyzed using immunoblotting. In all experiments, microtubule integrity was assessed
by 1) immunofluorescent labeling/fluorescence microscopy to determine
the percentage of cells with normal microtubules, 2) detailed analysis
by high-resolution laser scanning confocal microscopy (LSCM), and 3)
quantitative immunoblot analysis of monomeric and polymerized tubulin
and oxidation and nitration of these tubulin fractions as described below.
Determination of Cell Integrity.
Live/Dead kits (Molecular
Probes, Eugene, OR) were used. This assay measures parameters of cell
death: nuclear membrane integrity and chromatin condensation by
ethidium homodimer-1 probe, as we described previously (Banan et al.,
1999a).
Determination of Epithelial Barrier Function by Fluorometry.
Barrier integrity was determined by measuring apical-to-basolateral
flux of a fluorescent marker [fluorescein sulfonic acid (FSA), 200 µg/ml, 478 Da); Molecular Probes] as previously described (Unno et
al., 1996; Banan et al., 1999a). After pharmacological treatments,
fluorescent signals from samples were quantified using a fluorescence
multiplate reader. The excitation and emission spectra for FSA were
excitation = 485 nm and emission = 530 nm. Clearance (CL) was
calculated using the following formula: CL (nl/h/cm2) = Fab/([FSA]a × S), where
Fab is the apical to basolateral flux of FSA (light
units/h), [FSA]a is the concentration at
baseline (light units/nl), and S is the surface area (0.3 cm2) (Unno et al., 1996). Simultaneous controls
were performed with each experiment.
Assay of iNOS Activity.
Cells grown to confluence were
removed by scraping, centrifuging, and homogenizing on ice in a buffer
containing 50 mM Tris-HCl, 0.1 mM EDTA, 0.1 mM EGTA, 12 mM
2-mercaptoethanol, and 1 mM phenylmethylsulfonyl fluoride (pH 7.4). The
homogenates were incubated with a cation-exchange resin (AG 50W-X8,
Na+ form; Sigma Chemical Co.) for 5 min on ice to
deplete endogenous L-Arg. Conversion of
L-[3H]Arg (Amersham Corp.,
Arlington Heights, IL) to
L-[3H]citrulline was measured in
the homogenates by scintillation counting, as previously described
(Salzman et al., 1996; Banan et al., 1999a). Experiments in the absence
of NADPH or in the presence of NOS inhibitor L-NMMA (1 mM)
determined the extent of
L-[3H]citrulline formation
independent of NOS activity. Experiments in the presence of NADPH,
without Ca2+ and with 5 mM EGTA, determined
Ca2+-independent NOS (iNOS) activity. In selected
experiments, the isoform-selective iNOS inhibitor L-NIL was
also present (see earlier). Protein concentrations were determined
according to the Bradford method (Bradford, 1976).
Western Blot Analysis of Level of iNOS Protein.
After
treatment with EtOH or vehicle, the cells were washed once with cold
PBS, scraped in 1 ml of cold PBS, and harvested in an antiprotease
cocktail (2 µg/ml aprotinin, 2 µg/ml pepstatin, 2 µg/ml
leupeptin, and 2 µg/ml phenylmethylsulfonyl fluoride). Protein
content was determined according to the Bradford method (Bradford,
1976). For immunoblotting, samples (25 µg of protein/lane) were added
to SDS buffer (250 mM Tris-HCl, pH 6.8, 2% glycerol, 5%
mercaptoethanol), boiled for 5 min, and then separated on 7.5% SDS-polyacrylamide gel electrophoresis. Subsequently, proteins were
transferred to nitrocellulose membranes and then blocked in 3% BSA for
1 h followed by several washes (Tris-buffered saline). The
immunoblotted proteins were incubated for 2 h in Tween 20 and
Tris-buffered saline and 1% BSA with the primary antibody (mouse
monoclonal anti-human iNOS, 1:3000 dilution; Santa Cruz Biotech, Santa
Cruz, CA). A horseradish peroxidase (HRP)-conjugated goat anti-mouse
antibody (Molecular Probes, Eugene, OR) was used as a secondary
antibody at 1:3000 dilution. Membranes were visualized by enhanced
chemiluminescence (ECL; Amersham) and autoradiography (Singer et al.,
1996).
Chemiluminescence Analysis of NO Concentration in Cultures.
NO production was assessed by a novel and sensitive chemiluminescence
procedure (Al-Mufti et al., 1998). Briefly, cells were homogenized by
sonication, and the endogenous nitrate
(NO3) and nitrite
(NO2), the metabolic
degradation products of NO, were then reduced to NO using vanadium(III)
(Sigma Chemical Co.) and HCl at 90°C before the measurement of NO
concentration by chemiluminescence analysis. Chemiluminescence was
measured using a Seivers NOA 280 analyzer (Sievers, Boulder,
CO). NO was expressed in micromolar and calculated by comparison
with the chemiluminescence of a standard solution of
NaNO2. The absolute NO values were reported as
micromoles per 1 × 106 cells.
Determination of Cell Oxidative Stress and Superoxide Anion
Production.
Oxidative stress and superoxide anion
(O
2) production were assessed by measuring the
conversion of a nonfluorescent compound, 2',7'-dichlorofluorescein diacetate (DCFD; Molecular
Probes) into a fluorescent dye, dichlorofluorescein (DCF) as
previously described (Wakulich and Tepperman, 1997; Banan et al.,
1999a). The dependence of the assay on monolayer O2 generation
was shown by adding an active superoxide radical scavenger, SOD (300 U/ml), or an inactive superoxide radical scavenger, iSOD. Briefly,
monolayers grown in 96-well plates were preincubated with the
membrane-permeable DCFD (10 µg/ml for 30 min) before the subsequent
treatments (see experimental series 1 and 3). After treatments,
fluorescent signals (i.e., DCF fluorescence) from samples were
quantified using a fluorescence multiplate reader set at an excitation
wavelength of 485 nm and an emission wavelength of 530 nm.
Immunofluorescent Staining and High-Resolution LSCM of
Microtubule Cytoskeleton.
Cells from monolayers were fixed in
cytoskeletal stabilization buffer and then postfixed in 95% EtOH as
previously described (Allen, 1985; Banan et al., 1998a,b). Cell
monolayers were subsequently processed for incubation with primary
monoclonal mouse anti-
-tubulin antibody (IgG1,
rat/human reactive; Sigma Chemical Co.) at 1:200 dilution for 1 h
at 37°C. Slides were washed three times in Dulbecco's PBS
(D-PBS) and then incubated with a secondary antibody
(fluorescein isothiocyanate-conjugated goat anti-mouse; Sigma Chemical
Co.) at 1:50 dilution for 1 h at room temperature, washed three
times in D-PBS and once with deionized H2O, and
subsequently mounted in Aquamount. All antibodies were diluted with
D-PBS containing 0.1% BSA. Samples were stored in the dark at 
20°C
and were examined by both standard fluorescent and LSCM (Zeiss, Munich,
Germany). Cell monolayers on slides were observed in a blinded
fashion with LSCM using a 63× oil immersion plan-Apochromat objective,
NA 1.4 (Zeiss). An argon laser (
= 488 nm) was used to examine
fluorescein isothiocyanate-labeled cells, and the cytoskeletal elements
were examined for their overall morphology, orientation, and disruption as previously described (Banan et al., 1998b).
Microtubule (Tubulin) Fractionation and Quantitative
Immunoblotting of Tubulin.
Polymerized (S2) and monomeric (S1)
fractions of tubulin were isolated as we previously described (Banan et
al., 1998a,b). Fractionated S1 and S2 samples were flash frozen in
liquid N2 and then stored at 70°C until
immunoblotting. For immunoblotting, samples (5 µg) were placed in SDS
sample buffer (250 mM Tris-HCl, pH 6.8, 2% glycerol, 5%
mercaptoethanol), boiled for 5 min, and then subjected to
electrophoresis on 7.5% polyacrylamide gels. Procedures for Western
blotting were performed at room temperature (Banan et al., 1998b). To
quantify the relative levels of tubulin, the absorbance of the bands
corresponding to immunoradiolabeled tubulin was measured with a laser
densitometer. We ensured equal loading of proteins in all Western blots
by always loading 5 µg of protein/lane assessed according to the
Bradford method (Bradford, 1976). Experimental variations were further
minimized by the loading of 5 µg of standard tubulin, which was
tested concurrently with each gel. To further ensure reproducibility,
each treatment group was run in duplicate and/or triplicate on
different days.
Immunoblotting Determination of Tubulin Oxidation and Tubulin
Nitration.
Oxidation and nitration of the tubulin backbone of
microtubules were assessed by measuring protein carbonyl and
nitrotyrosine formation, respectively (Banan et al., 1999c, 2000a;
Ferro et al., 1997). Carbonylation and nitrotyrosination of tubulin
were determined in a similar manner as the quantitative blotting of tubulin (Banan et al., 1998b) except for differences in primary antibodies and buffers. To avoid unwanted oxidation of tubulin samples,
all buffers contained 0.5 mM dithiothreitol and 20 mM 4,5-dihydroxy-1,3-benzene sulfonic acid (Sigma Chemical Co.). To
determine the carbonyl content, samples were blotted onto a polyvinylidene difluoride membrane, followed by successive incubations in 2 N HCl and 2,4-dinitrophenylhydrazine (DNP; 100 µg/ml in 2 N HCl;
Sigma Chemical Co.) for 5 min each. Membranes were then washed three
times in 2 N HCl and subsequently washed seven times in 100% methanol
for 5 min each, followed by blocking for 1 h in 5% BSA in 10×
PBS/Tween 20 (PBS-T). Immunologic evaluation of carbonyl formation was
performed for 1 h in 1% BSA/PBS-T buffer containing anti-DNP
(1:25,000 dilution; Molecular Probes). Membranes were then incubated
with an HRP-conjugated secondary antibody (1:4000 dilution, 1 h;
Molecular Probes, Eugene, OR). To determine nitrotyrosine content,
after the blocking step earlier (i.e., BSA/PBS-T buffer), membranes
were probed for nitrotyrosine by incubation with 2 µg/ml monoclonal
anti-nitrotyrosine antibody for 1 h (Upstate Biotechnology, Lake
Placid, NY) followed by the HRP-conjugated secondary antibody (as
earlier). Wash steps and film exposure were as previously described
(Banan et al., 1998b). The relative levels of oxidized or nitrated
tubulin were then quantified by measuring, with a laser densitometer,
with the absorbance (A) of the bands corresponding to
anti-DNP or anti-nitrotyrosine immunoreactivity. Immunoreactivity was
expressed as the fraction (ratio) of carbonyl or nitrotyrosine
formation in the treatment group to that in the oxidized or nitrated
tubulin standard run concurrently.
Statistical Analysis.
Data are presented as mean ± S.E. All experiments were carried out with a sample size of at least
four to six observations per group. Statistical analysis between or
among groups was carried out using ANOVA followed by Dunnett's
multiple range test (Harter, 1960). Correlational analyses were
performed using the Pearson test for parametric analysis or, when
applicable, the Spearman test for nonparametric analysis. For all
analyses, a value of P < .05 was deemed to represent
statistical significance.
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Results |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Injurious Effects of EtOH on Monolayer Barrier Integrity
and Its Prevention by a Selective iNOS Inhibitor.
Caco-2
monolayers exposed to a range of concentrations of EtOH (1, 2.5, and
15%) for 30 min showed a dose-dependent loss of epithelial barrier
function as demonstrated by increased clearance of FSA (Fig.
1). The lowest dose of EtOH that
significantly increased FSA clearance was 2.5%. Under these condition,
EtOH does not cause cell death as determined by ethidium homodimer-1
probe (Banan et al., 1999a). Pretreatment with a selective iNOS
inhibitor (L-NIL) significantly attenuated the
EtOH-induced disruption of barrier integrity by up to 65%.
Preincubation with an NOS substrate, L-Arg (48 h),
synergized with 1% EtOH to create an injurious effect and potentiated
the monolayer barrier dysfunction induced by 2.5 and 15% EtOH.
L-Arg by itself did not significantly affect monolayer barrier function. Pretreatment with L-NIL completely
abolished the "potentiating" interaction between L-Arg
and EtOH (Fig. 1). Similar to L-NIL, 1-h preincubation with
nonselective NOS inhibitors (L-NMMA or
L-NNA) significantly protected against barrier
dysfunction by EtOH (FSA clearance = 1223 ± 53 nl/h/cm2 for L-NMMA or 1309 ± 93 for L-NNA versus 2548 ± 105 for 15% EtOH). One-hour incubation with L-NMMA or L-NNA by
itself did not significantly affect FSA clearance compared with vehicle
(not shown).
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NO-Dependent Oxidative Mechanisms in Injurious Effects of
EtOH.
Similar to L-NIL, the
ONOO scavengers urate and
L-cysteine and the O2 scavenger SOD significantly
attenuated the loss of barrier integrity induced by EtOH (Table
1; cysteine and SOD shown). The analogs
D-cysteine and iSOD were ineffective.
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2 is a key radical for this oxidative stress, we
preincubated monolayers with SOD. We showed (Fig. 4B) that SOD quenched
the DCF signal to control levels, whereas iSOD did not. This confirms
O2 generation by EtOH.
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Role of NO-Dependent Mechanisms in Deleterious Effects of EtOH on
Microtubule Cytoskeleton.
EtOH dose-dependently decreased
microtubule stability (to 27% of control) as determined by laser
confocal microscopy and as indicated by the reduced percentage of cells
displaying normal microtubules (see Table
2). Similar to effects on barrier
function, the lowest EtOH dose that significantly induced instability
of microtubules was 2.5%. Additionally, there was a significant
(P < .05) positive correlation (r = 0.98) between EtOH doses and percentage of cells with abnormal
microtubules. Preincubation with the selective iNOS inhibitor
L-NIL or with antioxidants (urate, L-cysteine, or SOD) markedly and significantly
blunted the EtOH-induced microtubule instability (Table 2).
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generation, namely nitrotyrosine and carbonyl moieties, on the tubulin
backbone of the microtubules using immunoblotting. Figure
6A shows that EtOH caused polymerized
tubulin (S2) nitration and oxidation. Quantitative immunoblotting shows
the fraction of polymerized tubulin (S2) that was nitrated (0.71 ± 0.03%) or oxidized (0.75 ± 0.01%) after exposure to 2.5%
EtOH. Preexposure of monolayers to the same iNOS inhibitor or
antioxidants as shown in Table 2 significantly prevented the nitration
and oxidation of tubulin (Fig. 6B, nitration shown). Analogues and/or
inactive forms of these antioxidant did not protect. Representative
Western immunoblots of anti-DNP (Fig. 7A)
and antinitrotyrosine (Fig. 7B) show the aforementioned treatment
regimens. There was a significant (P < .05) positive
correlation between microtubule instability and tubulin oxidation
(r = 0.98) and tubulin nitration (r = 0.95).
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Cytoskeletal and Barrier Disruption Induced by ONOO
Compounds.
Our hypothesis predicts that authentic
ONOO- or
ONOO-generating systems will, similar to EtOH,
induce cytoskeleton and monolayer injury by themselves. Indeed, the
disruption of monolayer barrier function (increased FSA clearance; Fig.
9A) was caused by incubation 1) with a
range of concentrations of authentic added ONOO
or 2) with known ONOO donors [e.g., SIN-1 (an
NO and O anion donor) or SNAP (an NO donor) in combination with
xanthine (X) plus xanthine oxidase (XO) (an O anion donor)]. These
effects were prevented by the antioxidants urate,
L-cysteine, or SOD but not by D-cysteine or iSOD (Fig. 9B, data for ONOO and SIN-1 shown).
At the same concentration (3 mM), D-cysteine was much less
protective than L-cysteine (4 versus 94%, respectively). To confirm that this difference in the protective capabilities of
cysteine isomers is related to their ability to scavenge
ONOO, we measured their scavenging ability in
vitro in the presence of added ONOO (absorbance
change at 302 normalized to percentages). L-Cysteine (3 mM)
removed more than 95% of exogenously added
ONOO, whereas D-cysteine (3 mM)
removed less than 15% of added ONOO.
Furthermore, ONOO compounds did not
significantly affect cell viability assessed by ethidium homodimer-1
(not shown). SNAP by itself did not induce barrier dysfunction (not
shown).
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compounds not only induced a
dose-dependent oxidation and nitration of the tubulin-based
cytoskeleton (Table 3) but also
disassembled the microtubules as shown by decreased stable S2 tubulin
and increased unstable S1 tubulin (Fig.
10A). Antioxidants almost completely abolished both the microtubule oxidation and nitration (Table 3) and
microtubule disassembly (Fig. 10A) that was induced by the
aforementioned ONOO compounds.
Immunofluorescent staining demonstrated (Fig. 10B) that
ONOO causes microtubule fragmentation, kinking,
and collapse (panel b) and pretreatment with L-cysteine
(panel c) protected the microtubules against
ONOO-induced damage as indicated by their
normal array, resembling the controls (panel a).
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Discussion |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Characterizing the pathophysiological mechanism for
ethanol-induced barrier dysfunction, as we tried to do in this study, is clinically important because the leaky gut has been proposed to be
one of the underlying mechanisms of alcohol-mediated endotoxemia in
patients with alcoholic liver disease (Bode et al., 1987; Hollander, 1992; Keshavarzian et al., 1994, 1999). We hypothesized that the cytoskeletal disruption (and barrier dysfunction) that is induced by
EtOH requires iNOS activation, NO overproduction, and
ONOO formation and that it is these free
radical reactions that lead to the oxidative injury to the
tubulin-based backbone of the microtubule cytoskeleton. We conclude
that all three separate lines of our investigation confirm the
hypothesis: 1) measurement of oxidative reactions and cytoskeletal
injury after EtOH administration, 2) mimicking EtOH-induced damage
using ONOO-generating systems, and 3)
preventing EtOH-induced cytoskeletal instability using NOS selective
inhibitors and antioxidants. The following section elaborates on this conclusion.
First, we found that under conditions where EtOH oxidizes tubulin,
disrupts the microtubule cytoskeleton, and diminishes barrier integrity
in cell monolayers, it also creates oxidative stress, including
increased levels of O2 (SOD quenchable DCF fluorescence), NO,
and ONOO. These associations strongly suggest
that the underlying cause of the injury to the cytoskeletal network
(and loss of barrier function) is the oxidation and nitration of its
structural tubulin subunits. This mechanism is further supported by a
highly significant correlation between increases in NO and
nitrotyrosine levels (r = 0.985); increases in
nitrotyrosine levels, and either abnormal microtubules
(r = 0.95) or microtubule depolymerization
(r = 0.94). Also, oxidation in general (as measured by
DCF or carbonyl moieties) predicts increases in abnormal microtubules
(r = 0.91 and 0.98, respectively).
These data suggest that the reaction between O2 and NO to form
ONOO is important in EtOH-induced damage. This
is consistent with previous studies that have documented that
O2 reacts rapidly with NO to form ONOO
(Hue and Padmaja, 1993). In our studies, evidence of
ONOO generation by EtOH was confirmed by using
a O2 scavenger, SOD, to prevent the interaction of O2
and NO. This conclusion was further supported by the fact that
ONOO scavengers (urate and
L-cysteine) also inhibited EtOH-induced cytoskeletal damage
(and barrier dysfunction). The demonstration that EtOH administration
increases NO and O2 and at the same time leads to increases in
stable ONOO footprints (tubulin-associated
nitrotyrosine and carbonyl) further corroborates our interpretation.
Our findings are consistent with earlier reports. For example, previous
in vivo studies also implicated oxidative stress and generation of free
radicals as key to the pathogenesis of a variety of GI disorders,
including EtOH-mediated injury (Kvietys et al., 1990; Keshavarzian et
al., 1992; Dinda et al., 1996; McKenzie et al., 1996).
ONOO-mediated damage is not limited to the GI
tract and has been proposed for other organs. For example, alterations
in lung function mediated by tumor necrosis factor (TNF)-
were
proposed to stem from nitrated proteins such as SOD, antiproteases, and
glutathione (Phelps et al., 1995).
Also, studies of systemic diseases and inflammatory GI disorders have
shown that oxidation and nitration of proteins occur in vivo and that
they can serve as markers of oxidative injury (Haddad et al., 1994;
Ischiropoulos et al., 1995; McKenzie et al., 1996; Singer et al., 1996;
Ferro et al., 1997). For example, recent studies have shown increased
nitrotyrosine and iNOS up-regulation in the inflamed intestinal
epithelium in vivo (Salzman et al., 1996; Singer et al., 1996; Kimura
et al., 1998). Moreover, it appears that ONOO
can oxidize a variety of essential molecules (e.g., sulfhydryls, thiols, ascorbate) and trigger injurious processes, including lipid
peroxidation (Muijsers et al., 1997). Indeed, a major product of the
reaction of ONOO with proteins (e.g., in
macrophages, in lung tissue) is the addition of a nitro group in the
ortho position of tyrosine to form nitrotyrosine (Ischiropoulos et al., 1992, 1995).
Second, we showed using ONOO or two different
ONOO-generating systems that
ONOO mimics the ability of EtOH to disrupt
barrier function and to oxidize and damage microtubules. These findings
are in accord with previous pharmacological studies in endothelial
cells, in test-tube models, and in inflammatory processes
(Ischiropoulos et al., 1992, 1995; Radi et al., 1993; Kooy and Royall,
1994; Haddad et al., 1994; Rachmilewitz et al., 1995). For example, ONOO not only can cause chemical oxidation of
luminol in the test-tube but also oxidatively injures endothelial cells
(Radi et al., 1993; Phelps et al., 1995). Our finding that
ONOO can disrupt intestinal barrier function is
in accord with finding by Ferro et al. (1997) for endothelial barrier
dysfunction. They showed that p42 oxidation and barrier dysfunction
induced by TNF- were both mediated by NO and
ONOO.
Third, we showed that agents that scavenge ONOO
or diminish the formation of ONOO from NO and
O2 attenuate the deleterious effects of both EtOH- and
ONOO-generating systems. Our findings parallel
a previous study (Phelps et al., 1995) in which urate and SOD protected
against TNF--induced, ONOO-mediated lung
endothelial injury. Interestingly, some of these same antioxidant
enzymes (e.g., SOD) and free radical scavengers (e.g., uric acid) are
normal constituents of all tissues (Muijsers et al., 1997). Similarly,
a previous study in vivo in rat lung showed that inhibition of NO
synthesis abolished the increases in protein nitrotyrosine and protein
carbonyl levels (Ischiropoulos et al., 1995).
In our studies, we checked the specificity of the protective effects of
antioxidants. First, we showed that analogs that lack the biological
activity of these protective agents (iSOD and D-cysteine) were neither capable of protecting against EtOH-induced loss of epithelial barrier function nor had any stabilizing effects on tubulin
or on microtubules. iSOD lacks the ability to scavenge O2 and
thus cannot inhibit the reaction of O2 + NO 
ONOO. We surmise that D-cysteine
does not protect against EtOH-induced damage because it is much more
poorly transported into the cell interior than L-cysteine,
which is the natural substrate for the amino acid carrier (Hopfer,
1987). We presume that intracellularly, L-cysteine
interacts directly with intracellular ONOO,
such as is generated during EtOH exposure. However, it is also possible
that L-cysteine enhances the antioxidant defenses of the
cell because it is a precursor of the natural antioxidant glutathione
(Van Klaveren et al., 1997).
Second, we directly measured ONOO footprints
(nitrotyrosine and carbonyl). Not only does this oxidation indicate
that added ONOO reaches the interior of our
cells but also attenuation of this oxidation indicates that urate and
L-cysteine are effective ONOO
scavengers. This is consistent with the conclusions of a previous study
(Radi et al., 1991).
The protective superiority of 3 mM L-cysteine over 3 mM
D-cysteine against added ONOO
obviously cannot be attributed to differential transport. It can be
attributed to our finding that D-cysteine (15% scavenging) is not equally effective as L-cysteine (95%) in scavenging
ONOO in solution.
Other observations we have made (Banan et al., 1999a, 2000a,c) showing
that growth factors protect against the injurious mechanisms induced by
EtOH or oxidants are consistent with the findings of this study. The
long-term goal of our laboratory is to clarify mechanisms of
EtOH-induced intestinal barrier dysfunction and then to find a means of
preventing this injury. Our current working hypothesis is that chemical
agents that are injurious to the intestinal tract (e.g., EtOH,
H2O2) cause iNOS
up-regulation. The activity of the iNOS enzyme leads to intracellular
increases in NO and ONOO that directly damage
(oxidize) cellular proteins such as tubulin. These effects on tubulin
disrupt the microtubule cytoskeleton, causing a loss in integrity of
the intestinal barrier, and predispose the organism to inflammation.
Clearly, other factors are involved in intestinal injury due to these
agents such as increases in intracellular calcium (Banan et al., 1999b)
and damage to the actin cytoskeleton (Banan et al., 2000b,c), but
microtubule damage appears to be responsible for a significant part of
this injury. The effect of growth factors (e.g., EGF) is to counteract
these deleterious effects (Banan et al., 1999a, 2000a,c) and to prevent or reverse iNOS induction and its sequelae. In this sense, chemically induced intestinal injury, on the one hand, and its prevention by
endogenous defense and repair mechanisms, on the other hand, appear to
modulate a single (iNOS-driven) pathway, in opposite directions.
Aspects of this model have recently received support from studies using
non-GI cell models in which EGF apparently inhibited iNOS up-regulation
(Heck et al., 1992; Schini et al., 1992; Asano et al., 1994). Further
studies are needed to elucidate the underlying mechanism through which
EtOH up-regulates iNOS and protective agents such as EGF may prevent
this up-regulation in the GI tract.
In conclusion, our present findings strongly suggest that the
underlying mechanism of intestinal epithelial barrier dysfunction induced by EtOH is due to oxidative injury to the cytoskeleton. Our
findings also provide avenues for development of novel therapies for
alcohol-induced GI disorders such as ONOO
scavengers, iNOS inhibitors, or antioxidants.
| |
Acknowledgment |
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We thank Dr. Rick Hutte at Sievers Inc. (Boulder, CO) for generous help with NO analysis.
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Footnotes |
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Accepted for publication May 31, 2000.
Received for publication February 9, 2000.
1 This work was supported in part by a grant from Rush University Medical Center. Portions of this work will be presented in the abstract form at the annual meeting of the American Gastroenterological Association in San Diego, CA, 2000.
Send reprint requests to: Ali Banan, Ph.D., Rush University Medical Center, Division of Digestive Diseases, 1725 W. Harrison, Suite 206, Chicago, IL 60612. E-mail: ali_banan{at}rush.edu
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Abbreviations |
|---|
GI, gastrointestinal; MT, microtubule; L-NIL, L-N6-1-iminoethyl-lysine; NO, nitric oxide; NOS, nitric-oxide synthase; iNOS, inducible NOS; EtOH, ethanol; EGF, epidermal growth factor; FSA, fluorescein sulfonic acid; SOD, superoxide dismutase; iSOD, heat-inactivated SOD; LSCM, laser scanning confocal microscopy; L-NNA, NG-nitro-L-arginine; HRP, horseradish peroxidase; L-Arg, L-arginine; L-NMMA, NG-monomethyl-L-arginine; DNP, 2,4-dinitrophenylhydrazine; DCF, dichlorofluorescein; DCFD, 2',7'-dichlorofluorescein diacetate; X, xanthine; XO, xanthine oxidase; SIN-1, 1,3-morpholinosydnonymine; SNAP, S-nitroso-N-acetyl penicillamine; D-PBS, Dulbecco's PBS.
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References |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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