(Received for publication, August 6, 1996, and in revised form, October 15, 1996)
From the Departments of Medicine and Pharmacology,
Division of Clinical Pharmacology, Thomas Jefferson University,
Philadelphia, Pennsylvania 19107 and § Departments of
Medicine and Pharmacology, Division of Cardiovascular Diseases, Mayo
Clinic, Mayo Foundation, Rochester, Minnesota 55905
Diarrhea induced by Escherichia
coli heat-stable enterotoxin (STa) is mediated by a
receptor guanylyl cyclase cascade. The present study establishes that
an intracellular nucleotide-dependent pathway disrupts
toxin-induced cyclic GMP (cGMP) production and the associated chloride
(Cl) flux that underlie intestinal secretion. Incubation
of Caco 2 human intestinal epithelial cells with the nucleoside analog 2-chloroadenosine (2ClAdo) resulted in a concentration- and
time-dependent inhibition of toxin-induced cGMP production.
Inhibition of cGMP production correlated with the metabolic conversion
of 2ClAdo to 2-chloroadenosine triphosphate. The effect of 2ClAdo did
not reflect activation of adenosine receptors, inhibition of adenosine deaminase, or modification of the binding or distribution of
STa receptors. Guanylyl cyclase activity in membranes
prepared from 2ClAdo-treated cells was inhibited, in contrast to
membranes from cells not exposed to 2ClAdo, demonstrating that
inhibition of guanylyl cyclase C (GCC) was mediated by a noncompetitive
mechanism. Treatment of Caco 2 cells with 2ClAdo also prevented
STa-induced Cl
current. Application of
8-bromo-cGMP, the cell-permeant analog of cGMP, to 2ClAdo-treated cells
reconstituted the Cl
current, demonstrating that
inhibition of Cl
flux reflected selective disruption of
ligand stimulation of GCC rather than the chloride channel itself.
Thus, the components required for adenine nucleotide inhibition of GCC
signaling are present in intact mammalian cells, establishing the
utility of this pathway to elucidate the mechanisms regulating
ST-dependent guanylyl cyclase signaling and intestinal
fluid homeostasis. In addition, these data suggest that the adenine
nucleotide inhibitory pathway may be a novel target to develop
antisecretory therapy for enterotoxigenic diarrhea.
Guanylyl cyclase C (GCC),1 the receptor for Escherichia coli heat-stable enterotoxin (STa) expressed in intestinal mucosa cells, is a member of the receptor guanylyl cyclase family that possesses receptor and catalytic domains on a single transmembrane protein (1, 2). Occupancy by STa of the extracellular receptor domain induces catalytic conversion of intracellular GTP to cyclic GMP (cGMP), resulting in sequential alterations in epithelial cell chloride flux, electrolyte and fluid secretion, and diarrhea (3, 4, 5, 6, 7). Interventions that specifically interrupt the STa-induced GCC-mediated signal sequence have not been defined. In cell-free systems, GCC is allosterically inhibited by 2-substituted adenine nucleotides (8, 9). Yet, the impermeance of intact cells to phosphorylated nucleotides and the absence of endogenous 2-substituted nucleotides has precluded the disruption of STa-induced signaling in intestinal cells through this inhibitory pathway. However, intestinal cells express transporters, which carry 2-substituted nucleosides into the cytosol, and adenosine kinase, which catalyzes conversion of 2-substituted nucleosides into 2-substituted nucleotides (10). The present studies examine whether that mechanism can be exploited to interrupt transmembrane signaling and alterations in chloride flux induced by STa in intact intestinal epithelial cells.
Caco 2 cells, well differentiated human colon carcinoma cells, were seeded in 24-well plates, allowed to reach confluence, and grown for an additional 14-21 days to ensure differentiation of these cells into colonic enterocytes. HEK293 cells, human embryonic kidney cells expressing recombinant GCC, were seeded in 24-well plates, allowed to reach confluence, and used for assays at least 5 days after seeding (1, 11). Cells were incubated in OPTI-MEM serum-free media (Life Technologies, Inc.) (0.5 ml/well) containing indicated concentrations of the test substances for the given period of time. Cells were washed three times with OPTI-MEM, then incubated in OPTI-MEM (0.2 ml/well) containing 0.12 mM isobutylmethylxanthine to inhibit endogenous phosphodiesterases for 10 min. STa was added to a final concentration of 0.5 µM for 10 min. Trichloroacetic acid (0.2 ml of 12% solution) was added to the wells to lyse the cells and terminate the reaction. Well contents were collected and centrifuged 15 min in a microcentrifuge to separate pellet and supernatant (8). The supernatant was collected, the trichloroacetic acid was removed by ether extraction, and the sample was used for cGMP determination by radioimmunoassay (12). Pellets were saved for determination of protein content by the method of Bradford (Bio-Rad).
Guanylyl Cyclase AssayCells were treated in OPTI-MEM media containing test substances as described above. Wells were washed three times with a Tris buffer (50 mM, pH 7.5) containing 1 mM EDTA, 1 mM dithiothreitol, and 1 mM phenylmethylsulfonyl fluoride (TED buffer) (8, 9). Cells were collected in TED and homogenized on ice. Homogenates were centrifuged at 100,000 × g for 60 min at 4 °C. Membranes were resuspended in TED with a final concentration of approximately 1 mg of protein/ml. Membranes were incubated at 37 °C for 5 min in 0.1 ml of a Tris buffer (50 mM, pH 7.5) containing 500 mM isobutylmethylxanthine, 7.5 mM creatine phosphate/20 mM creatine phosphokinase and either 10 mM MgGTP and 1 mM STa or 1 mM MnGTP. Enzyme reaction was terminated by addition of 0.5 ml NaAc (50 mM, pH 4.0) and boiling for 5 min. Cyclic GMP was quantified by radioimmunoassay as described previously (12).
STa Binding AssayFollowing membrane
preparation as described above, 30 µl of membrane were incubated in
50 mM Tris, pH 7.6, containing 1 mM EDTA, 150 mM KCl, 0.1% bacitracin, and 0.67 mM cystamine
(binding buffer). Binding was initiated by the addition of
125I-labeled STa (1013 to 5 × 10
8 M) (13). Reactions were incubated for
120 min at 37 °C and terminated by filtration on Whatman GF/B glass
fiber filters presoaked with 0.3% polyethyleneimine. Filters were
washed three times with 5 ml of buffer containing 150 mM
NaCl, 20 mM phosphate (pH 7.2), and 1 mM EDTA
at 4 °C. Specific binding was determined by subtracting nonspecific
binding (1000-fold excess of cold STa) from total binding.
Assays were performed in quadruplicate. Analysis of ligand binding was
performed using CIGALE, written by M. Bordes (Sophia Antipolis, France;
Ref. 13).
Cells were incubated with [8-3H]2Cl-adenosine (2ClAdo; 1 µM) in OPTI-MEM, and uptake was terminated with unlabeled 2ClAdo (1 mM) at indicated times. Washed cells were lysed with 6% trichloroacetic acid, extracts were centrifuged to collect supernatants, and radioactivity in supernatants was quantified. Nonspecific values were determined from experiments where the addition of cold 2ClAdo preceded addition of [8-3H]-2ClAdo. These values were subtracted from totals to obtain specific values (10). Pellets were used to determine protein content, and intracellular volumes were calculated using 3.66 µl/mg protein as reference (14). In unpublished experiments, to determine cation dependence, a buffer composed of 120 mM Na+ or K+, 20 mM Tris (pH 7.4), 3 mM Na2HPO4 or K2HPO4, 1 mM MgCl2, and 1.8 mM CaCl2 was used. No significant difference in the rate of uptake could be observed using this buffer or OPTI-MEM. Because all of the other experiments used OPTI-MEM, uptake experiments were done using OPTI-MEM.
High-performance Liquid Chromatography Determination of Nucleotide LevelCells were incubated as described above with 1 mM 2ClAdo for the indicated times and extracted with trichloroacetic acid; resulting supernatants were chromatographed on a Waters 12.5 nm, 10 µm µBondpack 3.9 × 300-mm C18 column, preequilibrated with a mobile phase (buffer A) containing 10 mM tetrabutylammonium hydroxide, 10 mM KH2PO4, and 0.25% MeOH, pH 7.0 (15). A step gradient was used with mobile phase buffer B (2.8 mM tetrabutylammonium hydroxide, 100 mM KH2PO4, and 30% MeOH, pH 5.5). The gradient was programmed as follows: 0-15 min, 100% buffer A; 20 min, 90% buffer A, 10% buffer B; 25 min, 70% buffer A, 30% buffer B; 40 min, 63% buffer A, 37% buffer B; 55 min, 55% buffer A, 45% buffer B; 75 min, 25% buffer A, 75% buffer B; 85 min, 0% buffer A, 100% buffer B for 10 min; at 125 min, 100% buffer A. Identification and quantification were achieved by comparing retention times of unknowns to standards. Intracellular nucleotide concentrations were calculated using the high-performance liquid chromatography-quantified molar amounts of nucleotide.
Perforated Whole-cell Patch Clamp Recordings of Caco 2 CellsThe perforated mode of the whole-cell patch clamp recording, which limits dialysis of intracellular signaling molecules, was applied to Caco 2 cells (16, 17). Membrane potential was controlled through the electrical access obtained by membrane perforation induced by amphotericin B (240 µg/ml) in the localized area under the patch pipette (3-5 megaohms). The bath solution contained 136.5 mM NaCl, 5.4 mM KCl, 1.8 mM CaCl2, 0.53 mM MgCl2, 5.5 mM glucose, and 5.5 mM Hepes-NaOH, pH 7.4. The pipette solution contained 140 mM K+-gluconate, 5 mM MgCl2, 1 mM EGTA, and 5 mM Hepes-KOH, pH 7.3. Voltage clamp recordings were obtained using a patch-clamp amplifier (Axopatch 1-C, Axon Instruments), and data were acquired and analyzed using BioQuest software (17).
Treatment of either Caco 2 cells natively expressing GCC or HEK293
cells heterologously expressing recombinant GCC with the nucleoside
2ClAdo, a metabolic precursor of 2ClATP, suppressed STa-induced cGMP accumulation (Fig.
1a). The effect of 2ClAdo was concentration
(Ki = 101 ± 21 µM; Fig.
1b)- and time-dependent (t1/2
of 10 h; Fig. 1c). The 2ClAdo effect appeared
temporally biphasic, because inhibition of STa-induced cGMP
accumulation was preceded by a transient increase in
STa-induced cGMP accumulation at early (t 4 h) timepoints (Fig. 1c). Although the mechanisms
underlying this initial transient rise in cGMP remain unclear, 2ClAdo
is a potent ligand for adenosine receptors, and activation of other signaling mechanisms through these receptors could activate GCC (18).
There was no significant difference in the number of cells or the
amount of recovered protein in control or 2ClAdo-treated cells. Removal
of 2ClAdo restored STa-dependent cGMP
accumulation (t1/2 of 6 h; Fig. 1c,
inset), suggesting that inhibition of cGMP synthesis did not
reflect cell death.
Adenosine analogs such as 2ClAdo are potent agonists for extracellular
purinergic receptors. Furthermore, 2ClAdo is a low potency inhibitor of
adenosine deaminase (19), an enzyme that regulates intracellular
nucleotide concentrations. However, the effects of 2ClAdo could not be
mimicked by N-ethylcarboxamidoadenosine, a purinergic
P1 agonist with similar receptor potencies to 2ClAdo, nor
by reversible (erythro-9-(2-hydroxy-3-nonyl)adenine) or
irreversible (deoxycoformycin) adenosine deaminase inhibitors (Fig.
2a; Ref. 20). These data suggest that
2ClAdo-dependent inhibition of GCC signaling does not
reflect the potency of this nucleoside for purinergic receptors or
competitive inhibition of adenosine deaminase.
125I-labeled STa bound to membranes prepared from Caco 2 cells incubated in the absence and presence of 2ClAdo in a concentration-dependent and saturable fashion. Scatchard analyses yielded curvilinear isotherms, suggesting the presence of high and low affinity ligand-binding sites in both 2ClAdo-treated and control cells (Fig. 2b). Equilibrium binding parameters derived from Scatchard analyses suggested that 2ClAdo treatment did not significantly alter the number or affinity of ligand receptors (Fig. 2b). Thus, in membranes from control and treated cells, respectively, the numbers of high affinity (Bmax, 2.1 ± 1.3 versus 2.9 ± 2.1 fmol/mg of protein) and low affinity (Bmax, 0.03 ± 0.02 versus 0.08 ± 0.05 pmol/mg of protein) binding sites were closely comparable. Similarly, the affinities of high (KD, 0.9 ± 0.5 versus 6.5 ± 6.1 pM) and low (KD, 1.3 ± 1.1 versus 4.5 ± 2.0 nM) affinity binding sites compared favorably in membranes from control and treated cells, respectively. Equilibrium binding parameters (values ± S.E.) obtained in the present studies compare closely with those reported previously for high and low affinity STa binding sites (13, 21, 22, 23). Similarly, 2ClAdo neither decreased the number of 125I-labeled STa binding sites on the cell surface nor increased the rate of 125I-labeled STa internalization in intact cells (data not shown; Ref. 24). Therefore, inhibition of GCC signaling could not be attributed to alterations in distribution, sequestration, or ligand binding characteristics of the receptor.
Caco 2 cells incorporated [8-3H]2ClAdo in a time-dependent fashion (Fig. 2c). Uptake of [8-3H]2ClAdo was not dependent on extracellular Na+, suggesting that intracellular accumulation was mediated by an equilibrative nucleoside transport mechanism (10). Iodotubercidin, an adenosine kinase inhibitor, did not alter the initial rate of uptake but prevented further increases in intracellular [8-3H]2ClAdo (data not shown). These data suggest that cellular nucleoside accumulation was dependent on transport coupled to metabolic conversion to a phosphorylated product (10, 20).
Although 2ClAdo inhibited STa-induced cGMP accumulation in
intact cells, this nucleoside did not suppress the activity of GCC in
intestinal cell membranes (Fig. 3a). However,
membranes prepared from intact cells pretreated with 2ClAdo did exhibit persistent inhibition of GCC (Fig. 3b). These data further
suggest that 2ClAdo undergoes intracellular metabolic conversion into the proximal allosteric inhibitor of GCC. High-performance liquid chromatography analysis of 2ClAdo-treated human intestinal cells revealed time-dependent accumulation of 2ClATP (Fig.
3c), which correlated closely with nucleoside inhibition of
STa-induced cGMP accumulation. In contrast to 2ClAdo (Fig.
3a), 2ClATP directly inhibited the activity of GCC in
intestinal cell membranes (Fig. 3c, inset). Iodotubercidin,
a competitive inhibitor of phosphorylation of 2ClAdo by adenosine
kinase, decreased the potency of 2ClAdo to inhibit
STa-induced cGMP production (Fig. 3d; Ref. 20).
Thus, 2ClAdo inhibits STa-induced cGMP accumulation in
intact cells following intracellular phosphorylation by adenosine
kinase, ultimately to 2ClATP, an effective allosteric inhibitor of GCC
(8, 9).
To determine the consequence of disrupting cGMP accumulation with
2ClAdo on STa-induced postreceptor signals, alterations in
chloride current were examined in human intestinal cells. In Caco 2 cells, STa induced an outward current (135 ± 33 pA at
a membrane potential of +10 mV, n = 4), which was
suppressed by removal of extracellular chloride or by the addition of
glyburide (Fig. 4a). The selectivity for
Cl outward rectification reversal potential at
70 mV
and pharmacological properties (Fig. 4, a and
a1) were all consistent with the presumed role
of the cystic fibrosis transmembrane conductance regulator in mediating
STa-induced alterations in chloride conductance in intestinal cells (25, 26, 27, 28). However, in Caco 2 cells treated with
2ClAdo, STa could no longer induce a chloride current (Fig.
4, b and c). Yet, in the same 2ClAdo-treated
cells, 8-bromo cGMP, a membrane-permeant cGMP analog (6), produced an
outward current that was abolished by removal of extracellular chloride
(Fig. 4b). Thus, 2ClAdo treatment specifically blocked STa-dependent signaling by inhibiting GCC and
accumulation of cGMP, rather than altering the ability of cGMP to
generate chloride currents.
The present studies establish an intracellular
nucleotide-dependent pathway for inhibition of GCC
signaling in intact human intestinal cells (Fig. 5).
Uptake and phosphorylation of 2ClAdo results in accumulation of 2ClATP,
which inhibits STa activation of guanylyl cyclase,
accumulation of cGMP, and subsequent chloride fluxes mediating
toxin-induced diarrhea. These data demonstrate that the components
required for 2-substituted adenine nucleotide inhibition of GCC
signaling are present in intact mammalian cells, establishing this
pathway as a tool for elucidating the molecular mechanisms regulating
GCC and intestinal fluid homeostasis. In addition, these data suggest
that the adenine nucleotide inhibitory pathway may be a novel target
for developing antisecretory therapy to treat enterotoxigenic
diarrhea.
We thank Drs. Stephanie Schulz and David Garbers for the generous gift of HEK293 cells stably expressing rat GCC and Dr. D. C. Robertson for the generous gift of ST.