Departments of 1Molecular Biomedical Sciences and 3Clinical Sciences, School of Veterinary Medicine, North Carolina State University, Raleigh 27606; and 2Department of Medicine, University of North Carolina, Chapel Hill, North Carolina 27514
Submitted 19 December 2002 ; accepted in final form 9 June 2003
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ABSTRACT |
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resistance; permeability; tight junction; deoxycholate
Gut barrier failure can be a life-threatening consequence of NSAID use and results in >100,000 hospitalizations per year at an estimated cost of $2,000,000,000 (17). Substantial information has been gathered concerning the protective attributes of endogenous PG and the role of PG depletion in the genesis of peptic ulcer disease in patients receiving NSAIDs. Considerably less is known about the effects of endogenous PG on barrier function of the small intestine. It appears that simple inhibition of cyclooxygenase is insufficient to cause functional or morphological injury to small intestinal mucosa. However, in the presence of preexisting inflammatory bowel disease or luminal aggressive factors such as bile and bacteria, NSAID therapy can be associated with increases in intestinal permeability and disease exacerbation (4, 5, 12, 19, 20, 33). Accordingly, PG may mediate reparative effects in the small intestine. Nonetheless, little attention has been given to clarifying the local mechanisms of PG action in the small intestine or to the determination of whether NSAIDs result in inadequate repair mechanisms.
We hypothesized that increased synthesis of endogenous PG plays a key role in the repair of preexisting small intestinal injury. Accordingly, we examined the local effects of PG on epithelial repair after deoxycholate-induced injury to porcine ileal mucosa mounted in Ussing chambers. The ileum is a common site for intestinal inflammation, bacterial deconjugation of bile acids, and exposure to high concentrations of enterohepatically recirculated NSAID. After deconjugation, bile acids contribute to injury by triggering increases in tight junction permeability and epithelial cell loss (14). Our in vitro model retains the physiological complexity of interactions between the lamina propria and overlying epithelium while eliminating effects mediated by PG in vivo, such as leukocyte adhesion, mucosal blood flow, and cell proliferation (16). Consequently, local mechanisms that affect villus contraction, epithelial cell migration, and tight junction permeability can be integrated and their contributions to recovery of barrier function quantified.
Results of the present study show that endogenous PG, released when mucosal injury occurs, mediate local repair of small intestinal epithelium after damage by the deconjugated bile salt deoxycholate. Whereas ongoing restitution and villous contraction were prominent features of repairing mucosa, acute recovery of barrier function was uniquely dependent on PG-mediated resealing of tight junctions and lateral intercellular space. Failure to repair increases in paracellular pathway permeability may underlie barrier failure resulting from NSAID use in patients with underlying enteropathy.
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METHODS |
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Ussing chamber studies. Ileal mucosa was separated from the seromuscular layers in an oxygenated (95% O2-5% CO2) Ringer solution and mounted in 3.14-cm2-aperture Ussing chambers. Tissues were bathed on both serosal and mucosal sides by a Ringer solution containing (in mM): 142 Na+, 5K+, 1.25 Ca2+, 1.1 Mg2+, 124 Cl-, 25 , 1.65
and 0.3
. The serosal solution contained 10 mM glucose, and the mucosal solution contained 10 mM mannitol. Solutions were oxygenated (95% O2-5% CO2) and circulated in water-jacketed reservoirs maintained at 37°C.
Electrical recordings were performed every 15-30 min and included short-circuit current (Isc) and spontaneous potential difference (PD). PD was measured using Ringer-agar bridges connected to calomel electrodes. If the PD was between -1.0 and 1.0 mV, tissues were current clamped at ±100 µA for PD measurement. PD was short circuited through Ag-AgCl electrodes using a voltage clamp that corrects for fluid resistance (World Precision Instruments, Sarasota, FL). Transepithelial electrical resistance (TER; ·cm2) was calculated from the spontaneous or clamped PD and Isc using Ohms' law.
Isotopic flux studies of epithelial permeability were performed using 3H-labeled mannitol (2 µCi; 6.6 mM; DuPont; Boston, MA) or 3H-labeled inulin (2 µCi; 0.2 mM; DuPont). Isotope was added to the mucosal reservoir immediately after removal of deoxycholate [time (t) = 30 min]. For 3H-labeled mannitol, three successive 60 min flux periods (from 30 to 210 min) were performed by taking paired samples from the serosal reservoir. For 3H-labeled inulin, five successive 30 min flux periods (from 60 to 210 min) were similarly performed. Samples were counted for 3H in a liquid scintillation counter (LKB Wallac, Turku, Finland). Flux of mannitol or inulin from mucosa to serosa was calculated using standard equations.
In vitro mucosal injury. All tissues were allowed to equilibrate in the Ussing chamber for 15 min (t = 0-15 min). Deoxycholate (6 mM; Sigma, St. Louis, MO) was then added to the mucosal reservoir for a duration of 15 min (t = 15-30 min). Deoxycholate was removed and replaced by Ringer solution, and tissue recovery was assessed over a 3-h period (30-210 min). The 210-min length of study was chosen based on declining viability of uninjured ileum within the Ussing chamber after this time period.
To standardize the severity of injury, tissues having TER <16 or >28 ·cm2 immediately after removal of deoxycholate were discarded from analysis. This injury results in a uniform degree of epithelial damage, which is partially repaired during the 3-h recovery period. Details of our experimental model of acute mucosal injury and repair have been published previously (16). For each pig, uninjured and injured but untreated tissues were included in all experimental designs.
Morphometric analyses. Tissues were removed from the Ussing chamber after specified time periods. A sample from each Ussing chamber was fixed in formalin, sectioned at 5-µm thickness, and stained with hematoxylin and eosin. Three sections from each tissue were examined without knowledge of prior treatment. With the use of an ocular micrometer and light microscope, the following measurements were recorded for five well-oriented villi and then averaged: 1) villus height measured from the crypt opening to villus tip, 2) crypt depth, 3) villus width at midpoint, 4) linear length of villus perimeter, and 5) linear length of denuded villus. To account for reductions in villus height and surface area that result from stripping and mounting of mucosa (24), measurements were compared with Ussing-chambered but uninjured tissue fixed at matching time points.
Villus surface area was calculated using a modified formula for calculating the surface area of a cylinder (3). The formula was modified by subtracting the area of each base of the cylinder, adding a factor accounting for the hemispherical shape of the apical villus, and multiplying by a factor accounting for the variable position at which each villus is frontally sectioned (22) as follows: villus surface area = 2 ·
[(4/
)d]h, where
= 3.14, d is villus diameter (width) at midpoint, and h is villus height.
Determination of the relative contributions of villi and crypts to total luminal surface area was performed as described by Collett et al. for rat ileal mucosa (10). Briefly, paraffin-embedded tissues were sequentially sectioned in a transverse orientation every 20 µm beginning at the base of the crypts and extending to the villus tips. The crypt surface length was measured in each section from the base of the crypt to its opening at the surface. Surface length of villi was measured from the opening of the crypt to the tip of the villus. Measurements were made using a computer software package (Image-Pro Plus; Media Cybernetics, Silver Spring, MD). Relative contributions of crypts and villi to total surface area were calculated as follows
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Transmission electron microscopy. To examine the ultrastructural effect of endogenous PGs on intercellular space anatomy of deoxycholate-injured porcine ileum, tissues were removed after 210 min in the Ussing chamber and placed in Trump's 4F:1G fixative at 4°C. Samples were processed for transmission electron microscopy using standard techniques (11).
Immunofluorescence microscopy. Tissues were removed from the Ussing chamber after 210 min, embedded in optimal cutting temperature medium, and frozen-sectioned at 5-µm thickness. Epitope retrieval was performed by boiling the slide-mounted tissue sections in citrate buffer (pH = 6) for 10 min. Sections were blocked with 2% BSA before incubation with rabbit anti-ZO-1 polyclonal antibody (1:250 in BLOTTO) or isotype control for rabbit primary antibody (Zymed Laboratories, San Francisco, CA) for 2 h at room temperature. After sections were rinsed in BLOTTO, they were incubated with goat anti-rabbit IgG Cy3 conjugate (1:300 in BLOTTO with 2% BSA; Zymed) for 45 min in the dark. Sections were rinsed in BLOTTO and PBS, counterstained with DAPI (50 µg/ml; Santa Cruz Biotechnology, Santa Cruz, CA), and placed on a coverslip with aqueous media containing 2.5% DABCO (Sigma). Sections were stored at -20°C. Well-oriented villi were examined using an immunofluorescence microscope.
Eicosanoid analyses. For eicosanoid analyses, paired samples were taken from the serosal reservoir, gassed with N2, and frozen in liquid N2. Samples were stored at -20°C before assay. Samples were analyzed for concentration of PGE and 6-keto-PGF1 (the stable metabolite of PGI2) using commercial ELISA kits according to the manufacturer's instructions (Biomedical Technologies, Stoughton, MA).
Assessment of PG effects on epithelial repair. Unless stated otherwise, treatments were added to tissues immediately after deoxycholate removal from the mucosal reservoir (t = 30 min). Treatments included 16,16-dimethyl-PGE2 (Sigma) and the PGI2 analog carbacyclin (Sigma; each 10-6 M serosal) and indomethacin (Indo; 5 x 10-6 M mucosal and serosal). 16,16-Dimethyl-PGE2 and carbacyclin were examined in combination based on prior studies demonstrating their synergistic action on recovery of barrier function after ischemic injury of porcine ileum (6) and increases in endogenous synthesis of both of these eicosanoids after deoxycholate injury in the present model.
Statistical analysis. Data are reported as means ± SE. For all analyses, P < 0.05 was considered significant. One-way or repeated-measures ANOVA and a post hoc Tukey's test were used to compare differences between treatment and control tissues. Pearson correlation coefficient was used to examine relationships between TER and morphological measurements under different treatment conditions (n is number of pigs receiving treatment).
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RESULTS |
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To determine the mechanisms responsible for recovery of barrier function, restitution was quantified by measuring the surface length of denuded and reepithelialized villus perimeters using an ocular micrometer. Both injured and uninjured tissues were examined after 0, 30, 45, 75, 150, and 210 min in the Ussing chamber (Fig. 2A). Immediately after replacement of deoxycholate with fresh Ringer solution (t = 30 min), there was detachment of enterocytes from the villus tips. Epithelial cell losses continued until t = 75 min. From 75 to 210 min, there was ongoing restitution by migrating flattened to cuboidal absorptive cells and a significant decrease in denuded villus surface area (24,951 ± 5,480 µm2 at 75 min; 10,350 ± 2,702 µm2 at 210 min; n = 8 each; *P < 0.05; 1-way ANOVA; Fig. 2B). Uninjured tissue remained covered by confluent epithelium for over 210 min if left unperturbed within the Ussing chamber.
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Villous contraction was quantified by measurements of villous height taken from injured and uninjured tissues after 0, 30, 45, 75, 150, and 210 min in the Ussing chamber. Deoxycholate injury and repair were associated with a rapid, followed by a gradual, phase of villous contraction (Fig. 2C). Initial contraction (I; 0-45-min) was acute and inclusive of deoxycholate injury. Subsequent contraction (II; 45-210 min) was ongoing throughout the repair period. Significant crypt contraction also accompanied mucosal repair. Morphometric analysis of injured tissue at 210 min revealed a villous-to-crypt surface area ratio of 1:1.8, indicating that the epithelialized crypts were responsible for the majority of the total mucosal surface area. Uninjured tissue retained 99.3 ± 13% of initial (poststripping) villus height, and 101.7 ± 9.5% of initial crypt depth, for >210 min if left unperturbed within the chamber (n = 4).
Endogenous PGs promote recovery of barrier function. Local synthesis of endogenous PGs increased significantly after acute deoxycholate injury [PGE: control = 4,410 ± 1,667; injured = 10,218 ± 3,862 pg/ml and PGI2 (6-keto-PGF1): control = 16,769 ± 6,338; injured = 24,714 ± 9,341 pg/ml]. Endogenous PG synthesis was inhibited by addition of a nonselective cyclooxygenase blocker immediately after injury (Indo; 5 x 10-6 M) (PGE = 496 ± 187; 6-keto-PGF1
= 1,726 ± 653 pg/ml; n = 7 each at 210-min; ***P < 0.001, Student's paired t-test).
To determine the role of increased PG synthesis in recovery of barrier function, Indo was added to the serosal and mucosal bathing solutions immediately after injury and before onset of repair (t = 30 min). Indo abolished recovery of TER (Fig. 3A) and increased permeability of the mucosa to 3H-labeled inulin (control = 1.47 ± 0.13 x 103 µmol/cm2·h; injured = 3.04 ± 0.38 x 103 µmol/cm2·h; injured + Indo = 4.2 ± 0.28 µmol/cm2·h at 210 min; n = 7 each; *P < 0.05, repeated-measures ANOVA). Recognizing the dependence on endogenous PG for recovery of barrier function, we determined whether additional PG could augment repair. Addition of exogenous PG [PGE2 (10-6 M) and carbacyclin (10-6 M; an analog of PGI2)] to the serosal bathing solution immediately after injury promoted an earlier increase in TER and decreased permeability to 3H-labeled inulin (control = 1.3 ± 0.11 x 103 µmol/cm2·h; injured = 3.04 ± 0.38 x 103 µmol/cm2·h; PG = 2.5 ± 0.23 µmol/cm2·h at 210 min; n = 9 each; *P < 0.05, repeated-measures ANOVA; Fig. 3A). Noteably, TER at the end of the 180-min repair period was not different between tissues having endogenous vs. exogenous PG exposure. These findings suggested that endogenous PG synthesis was sufficient to mediate the maximal repair response observed at 210 min.
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Restitution rate is independent of PG synthesis. In migration assays of wounded epithelial monolayers, PG appear to either mediate the action of growth factors (36) or trigger the downstream expression of growth factors that promote cell migration (35). To determine whether enhanced restitution was responsible for PG-mediated recovery of barrier function in the present model, surface reepithelialization was quantified in untreated, Indo and PG-treated tissues at 75 and 210 min to examine the basis for differences in TER at these time points (Fig. 3B). Neither Indo nor PG had any effect on percent reepithelialization of villi. However, in the presence of endogenous PG, TER appeared to relate positively with measures of epithelial restitution (including denuded villous surface length, calculated denuded villous surface area, and percent villous reepithelialization; P = 0.10), whereas in the absence of PG, no relationship between TER and restitution could be demonstrated (Fig. 4). Thus we could not attribute the effect of PG on TER to an underlying difference in restitution rate.
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Endogenous PGs mediate villus and crypt contraction. Prior in vivo studies have demonstrated that PG mediates a modest villous contraction that is insufficient in magnitude to hasten reepithelialization (13). However, because TER and isotopic permeability in vitro are expressed per unit of serosal surface area (i.e., in reference to the luminal aperture of the Ussing chamber), we sought to examine whether villous contraction was responsible for PG-dependent increases in TER, perhaps by condensing the surface area of the paracellular pathway within the remaining epithelium. Addition of Indo immediately after deoxycholate injury significantly inhibited contraction of both villi and crypts seen during the repair phase. The resulting villi had a greater total surface area involving a proportionate increase in both the denuded and epithelialized surface (Fig. 5). Villous contraction was not promoted by the addition of exogenous PG after injury. To determine whether PG additionally mediated the phase of villous contraction seen concurrent with deoxycholate injury, we treated tissues with Indo before injury and measured the height of villi immediately after removal of deoxycholate from the Ussing chamber. In the presence of Indo, the initial contractile phase of villi was not inhibited (villous height at 30 min; injured = 153.3 ± 22.8 µm; n = 8; injured + Indo = 97.4 ± 9.2 µm; n = 7). The difference in TER observed between tissues treated with and without Indo was not related to any measure of mucosal surface amplification (including villus height, villus width, crypt depth, total villous surface length, or calculated total villous surface area; P > 0.10). Thus PG-mediated effects on TER could not be attributed to stimulation of villous or crypt contraction.
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Contribution of restitution to recovery of epithelial barrier function. We were surprised to observe that in the presence of Indo, there was no recovery of TER despite an underlying 73% reepithelialization of the villi by 210 min. To determine whether a greater degree of epithelialization could promote recovery of TER in the presence of Indo, we stimulated restitution after injury by treating Ussing-chambered mucosa with L-arginine (Arg; 5 mM) and fetal bovine serum (FBS; 1%) as previously described (16). In the presence of Indo, Arg + FBS stimulated reepithelialization of villi from 73 ± 3 to 90 ± 2% despite the greater surface area resulting from concurrent arrest of villous contraction (Fig. 6, A and B). Even with restitution over a range of 49-100% of the villus surface, recovery of TER and decreases in 3H-labeled mannitol permeability were not observed in the absence of endogenous PG synthesis (Fig. 6, C and D).
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Endogenous PGs promote recovery of paracellular permeability. Because PG-dependent recovery of barrier function (210 min; Fig. 3A) could not be accredited to effects on restitution rate or villous contraction, we surmised that PGs exerted their effects on the paracellular pathway of the epithelium remaining after deoxycholate injury. To examine whether such a mechanism was reparative or could arise simply from effects of PG on normal epithelium, we examined the effect of Indo and exogenous PG on TER and 3H-labeled mannitol permeability of uninjured mucosa mounted in Ussing chambers. Neither Indo nor exogenous PG had any effect on TER or permeability when left in contact with uninjured mucosa for over 210 min (control = 57 ± 3.6 ·cm2 and 0.14 ± 0.02 µmol/cm2·h; PG = 54 ± 4.1
·cm2 and 0.15 ± 0.02 µmol/cm2·h; Indo = 54 ± 4.3
·cm2 and 0.15 ± 0.01 µmol/cm2·h at 210 min; n = 8 each). These results suggest that PGs augment recovery of leaky epithelium remaining after acute mucosal injury.
To determine whether a change in paracellular permeability alone was capable of influencing TER by magnitudes similar to that mediated by endogenous PG, we evaluated the effect of osmotic gradient-driven paracellular collapse on recovery of TER after deoxycholate injury. When urea (150 and 300 mosmol/kgH2O) was added to the mucosal reservoir immediately after injury and in the presence of Indo, TER increased to values comparable with that mediated by endogenous PG. Conversely, the addition of urea to the serosal reservoir in the presence of PG did not attenuate recovery of TER (Fig. 7). The asymmetric responsiveness of TER to osmotic gradients is a reported characteristic of bile salt-induced increases in tight junction permeability and has been attributed to enhanced conductance of the lateral intercellular spaces (14). Because prior studies have shown that PG-mediated tight junction closure is dependent, in part, on Cl- secretion, we additionally examined the effect of the Cl- secretion blocker bumetanide (Bum; 10-4 M) on recovery of TER after deoxycholate injury. Bum significantly inhibited recovery of TER in the presence of endogenous PG and without having effects on concurrent restitution or villous contraction (control = 57 ± 3.3; injured = 40 ± 3; injured + Bum = 29 ± 3.8 ·cm2; *P < 0.05, Student's paired t-test).
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We next sought to examine the effect of PG on the ultrastructural appearance of the tight junction and intercellular space of resident crypt and restituting epithelial cells at peak repair after deoxycholate injury (t = 210 min) (Fig. 8). In the presence of PG, the lateral membranes of crypt epithelial cells were tightly apposed. Epithelial cells migrating along the villus remained contiguous, both apically and basally, and were closely adherent to the underlying basement membrane. In tissues treated with Indo, however, crypt epithelium showed dilation of the lateral intercellular space below the tight junction. Epithelial cells migrating along the villus maintained only an apical attachment to neighboring cells with expansive separation of the lateral membranes and loss of contact with the basement membrane.
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To determine whether tight junction organization of the restituting villous epithelium was specifically altered in response to inhibition of PG synthesis, immunofluorescence microscopy for ZO-1 was performed using tissues obtained at peak repair (Fig. 9). In uninjured mucosa, ZO-1 was circumferentially localized along the periapical tight junctions. At peak repair, restituting epithelium showed continuous periapical ZO-1 labeling along the sides of the villi that became localized to junctional foci as cells dispersed along the villus tip. In contrast, mucosa treated with Indo revealed ZO-1 labeling with relatively diminished intensity and continuity.
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DISCUSSION |
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This conclusion is based on the following observations. First, whereas recovery of TER over time was paralleled by ongoing restitution as seen in prior studies (27, 31, 34), villous reepithelialization over a range of 49-100% was incapable of promoting recovery of barrier function in the absence of PG. Second, recovery of TER was not related to a decrease in total mucosal surface area. Third, in the absence of PG, independent manipulation of paracellular permeability with osmotic pressure gradients reproduced the TER measurements obtained in the presence of PG and without concurrent effects on restitution or villous contraction. Finally, paracellular space closure was mediated by an increase in endogenous PG synthesis after injury. Our finding that PG had no effect on restitution has been observed in other acute studies of intact mucosa (2, 6, 12). These results contrast those of PG effects on cell migration of wounded epithelial monolayers and may relate to the time required for induction of growth factor synthesis, which exceeds the duration of studies of early mucosal repair (<4 h).
Nevertheless, it is surprising that unimpeded restitution contributed little to early recovery of barrier function or conversely how any recovery of TER was possible in the presence of frank epithelial denudation. Deliberation of these issues necessitates considering the known barrier attributes of simple intestinal epithelia. TER represents the competence of the epithelium to defend itself against the passive permeation of ions. As such, TER is considered to be the most sensitive measure of epithelial barrier function. There exist two parallel routes by which ions can passively traverse the epithelium. The transcellular pathway entails crossing both the apical and basal plasma membranes of the epithelial cell. The paracellular pathway involves passing through the tight junction and lateral intercellular space (9, 23, 24, 30). Epithelial cell membranes have a high resistance to passive ion flow (1,000 to 10,000 ·cm2), whereas the overall resistance (TER) of mammalian small intestinal epithelium is only 21-100
·cm2 (30). Accordingly, the major determinant of TER is the integrity of the paracellular pathway, which has been calculated to account for 75-94% of the total passive ion flow across small intestinal epithelium (15, 29, 32). Thus agents that affect transcellular resistance have little relative effect on TER of these so-called "leaky" epithelia.
An important limitation of TER measurements are their inability to distinguish between changes in tight junction permeability and the presence of epithelial cell loss, both of which contribute to the overall surface area of low-resistance paracellular pathway. Thus recovery of TER after acute intestinal injury cannot be attributed to restitution alone without considering the possibility of simultaneous alterations in tight junction permeability; an assessment that requires a detailed dissection of the underlying mechanisms. Furthermore, if early recovery of TER is to be attributed to resealing of tight junctions more so than to restitution, the injury must result in a greater increase in surface area of the tight junctional pathway than the area of denuded epithelium created at the apical villus. The latter is a feasible consideration, because 63-73% of the total paracellular conductance of uninjured small intestinal epithelium is via a high linear density of tight junctions residing in the crypts (9, 10, 24), and after villous contraction, crypt epithelium accounts for the majority of surface area remaining after acute mucosal injury. To determine whether changes in tight junction permeability could theoretically account for the magnitude of TER observed in our model, we approximated total tight junction surface area using Marcial's measurements of 0.2180 µm paracellular pathway/µm2 surface area of villus and 0.7680 µm paracellular pathway/µm2 surface area of crypt (24) (APPENDIX). Given a total denuded and epithelialized villous surface area of 3.5 x 108 and 1.2 x 109 µm2, respectively (i.e., 75% reepithelialized), and total crypt surface area of 2.75 x 109 µm2 (64% of the total mucosal surface area) and the theoretical range in width of the tight junction (0.02-0.2 µm) (9) yields a range of tight junction surface area from 12 to 58% of the total surface area of low-resistance pathway (tight junction + denuded area). The 2.08-fold difference in total paracellular pathway resulting from changes in tight junction permeability well exceeds the 1.68-fold difference in TER measured in the presence vs. absence of endogenous PG synthesis. Accordingly, a PG-induced change in TER due exclusively to closure of the tight junction pathway is a feasible consideration.
Failure to close the intercellular spaces created by migration of epithelium can additionally explain why restitution was incapable of promoting recovery of barrier function in the absence of PG. The intercellular space represents a series component in the pathway of paracellular resistance. Resistance of the intercellular space (Ri) is given by the equation Ri = L/
lp, where
is resistivity of the bulk solution, L is length of the interspace,
is width of the interspace, and lp is linear amount of paracellular pathway per square centimeter of epithelium (9). Under conditions of tight apposition of the lateral membranes (
= 0.02 µm; Ref. 9), approximations of intercellular space resistance may exceed the specific tight junction resistance depending on the length of the intercellular space. The latter measurement is difficult to accurately estimate due to extensive folding of the lateral membranes lining the intercellular space (Fig. 8). However, once the intercellular space exceeds the physiological range in width of the tight junction (0.02-0.2 µm) (9), Ri approaches zero. Thus a PG-induced closure of intercellular space between resident and, in particular, restituting epithelial cells is likely to have also contributed to recovery of TER after deoxycholate injury.
Although we did not conduct a detailed investigation of the mechanism underlying the paracellular effects of PG, prior studies of PG action after ischemic injury of porcine ileum have demonstrated that PGE and PGI2 act synergistically to promote an osmotic-driven collapse of the tight junction and lateral intercellular space (7). The initiating event appears to involve stimulation of Cl- secretion that promotes withdrawal of Na+ and water from the paracellular spaces of the crypt (6). Concurrently, PGs inhibit neutral NaCl absorption resulting in decreased paracellular water absorption by the villus. Specific alterations by PG in tight junction structure are suggested by disruption of ZO-1 and occludin localization to the periapical tight junction in ischemia-injured tissues treated with Indo (21). Similar mechanisms are likely operative in the present model insofar as synthesis of both PGE and PGI2 were increased by deoxycholate injury, barrier function could be rescued in the absence of PG synthesis by application of a mucosal osmotic gradient, and PG-mediated recovery was partially inhibited by blockade of Cl- transport. Because localization of ZO-1 to periapical tight junctions was diminished after treatment of restituting mucosa with Indo, it is likely that a component of the action of PG on paracellular permeability in the present model involves restoration of normal tight junction structure.
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APPENDIX |
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Total crypt surface area was derived after determination that crypts contributed 64% and villi contributed 36% to total mucosal surface area of deoxycholate-injured tissue after 210 min in the Ussing chamber.
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Calculation of surface area of tight junction pathway. To estimate the surface area of tight junction pathway, we adopted the formula for linear density of tight junction pathway (lp; µm/µm2; Table A2) as defined by Claude (9) and measurements taken by Marcial et al. (24) of crypt and villus epithelium from Guinea pig ileum.
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Comparison of contributions of tight junction vs. denuded surface area to total low-resistance paracellular pathway. See table A3.
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DISCLOSURES |
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ACKNOWLEDGMENTS |
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FOOTNOTES |
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The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
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REFERENCES |
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