Hormonal regulation of chicken intestinal NHE and SGLT-1 activities

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Hormonal regulation of chicken intestinal NHE and SGLT-1 activities

Maria Carmen De La Horra, Mercedes Cano, Maria José Peral, Maria Luisa Calonge, and Anunciación Ana Ilundáin

Departamento Fisiología y Biología Animal, Facultad de Farmacia, Universidad de Sevilla, 41012 Sevilla, Spain

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The effects of aldosterone and arginine vasotocin (AVT) on intestinal Na⁺/H⁺ exchange (NHE) and Na⁺-sugar cotransport (SGLT-1) activities have been investigatedusing brush-border membrane vesicles isolated from Hubbard chickensmall and large intestines, and they were compared with thoseinduced by either Na⁺ depletion or dehydration. Na⁺ depletion was induced by feeding the chickens with either a low-or a high-Na⁺ diet for either 0.5, 1, 2, 4, or 8 days. Ileal and colonic NHE2activity increased with the duration of the Na⁺ depletion, whereas that of intestinal SGLT-1 decreased, reachinga plateau after 2 days of treatment. Three-hour incubation ofthe intestine with aldosterone produced the same effects on NHEactivity as does Na⁺ depletion, without altering SGLT-1 activity. However, 3-h incubationof the intestine with AVT increased intestinal SGLT-1 activity,without affecting intestinal NHE activity. It is concluded thataldosterone regulates apical ileal and colonic NHE2 activity,whereas that of SGLT-1 is regulated byAVT.

low-Na⁺ diet; aldosterone; arginine vasotocin; brush-border membrane vesicle; sodium/hydrogen exchange

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

IN MAMMALS, THE KIDNEY and the large intestine are the major regulators of body electrolyte and water homeostasis. As birdsdo not have a urinary bladder, the urine is emptied into the cloaca,and retrograde flow carries urine into the coprodeum, the colon(rectum), and cecum. As a result, the epithelia of the lower intestineprocess the ileal and ureteral outflow. We previously reportedthat dietary Na⁺ depletion decreased Na⁺-sugar cotransport (SGLT-1) activity and increased that of apicalsodium/hydrogen exchange (NHE) in the chick ileum and colon (6,7). We also showed (6) that 4 days of water deprivationincreased the activities of both apical NHE and SGLT-1 in jejunum,ileum, and colon of the chicken. Therefore, Na⁺ depletion decreased intestinal SGLT-1 activity, whereas it wasincreased by dehydration. Because both treatments increased plasmaaldosterone levels, it was concluded that aldosterone does notregulate intestinal SGLT-1 (6).

The purpose of the current work was to investigate in brush-border membrane vesicles (BBMV) isolated from chicken small andlarge intestine the time course of the effects of Na⁺ depletion on intestinal NHE and SGLT-1 activities and the effectsof aldosterone and arginine vasotocin (AVT) on those Na⁺-linked transport systemsactivities.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Solutions. For ²²Na⁺ uptake experiments, the intravesicular buffer contained (in mM) 140 mannitol, 50 K-gluconate, and 50 Mes-Tris (pH 5.5).The uptake buffer consisted of (in mM) 140 mannitol, 50 K-gluconate,0.045 valinomycin, 0.1 Na-gluconate, tracers of ²²Na⁺, and either 50 Mes-Tris (pH 5.5) or 50 HEPES-Tris (pH 7.5). Thestop solution contained (in mM) 140 mannitol, 50 K-gluconate,50 Mes-Tris (pH 5.5), and 0.1 amiloride. The protein concentrationper assay tube was 100-150 µg/100 µl of uptakebuffer.

$alpha$ -Methyl-glucopyranoside ( $alpha$ -MG) uptake was measured in BBMV loaded with (in mM) 140 mannitol, 50 K-gluconate, 0.1 MgSO₄, and50 HEPES-Tris (pH 7.5). The extravesicular buffer contained (inmM) 140 mannitol, 50 Na-gluconate, 0.1 $alpha$ -MG, 0.045 valinomycin,and tracers of $alpha$ -[D-¹⁴C]MG and 50 HEPES-Tris (pH 7.5), with or without 0.25 phlorizin.The stop solution contained (in mM) 140 mannitol, 50 HEPES-Tris(pH 7.5), 50 K-gluconate, and 0.25 phlorizin. The protein concentrationper assay tube was 100 µg/100 µl of uptakebuffer.

The everted small and large intestines were incubated for 3 h in a solution containing (in mM) 90 mannitol, 80 NaCl, 1 CaCl₂,1 MgCl₂, 3 K₂HPO₄, 25 HCO₃ choline (pH 7.4), and the desired hormone,and it was continuously bubbled with 95% O₂ and 5% CO₂. The mediumwas also supplemented with 10 mM glucose, 100 U/ml penicillin,and 100 µg/ml streptomycin. The pH of the solution was controlledthroughout theexperiment.

Animals and diets. Two groups of Hubbard chickens, 10 wk old, were adapted, before being killed, for either 0.5, 1, 2, 4, or 8 days to eithera high-NaCl diet or a low-NaCl diet as described (14). The low-NaCltreatment consisted of low-NaCl balanced food and demineralizedwater containing 1 mM CaCl₂. The high-NaCl treatment consistedof high-NaCl balanced food and demineralized water containing1 mM CaCl₂ plus 0.5% NaCl (wt/vol).

Another group of chickens was fed a commercial diet for 10 wk. After chickens were killed with an intravenous injection ofurethane, the small and large intestines were removed, openedlongitudinally, rinsed clean with ice-cold saline solution, andincubated for 3 h in the absence or presence of either 0.5 µMaldosterone or 0.5 µMAVT.

Plasma analysis. Blood samples were collected from a wing vein into ice-cold heparinized tubes and centrifuged immediately at 4°C. Plasma aldosteronewas measured by radioimmunoassay by Cerba laboratories (Barcelona,Spain). Na⁺ and K⁺ were measured by flame photometry and osmolality with an osmometer(Osmometer Gonotec, Osmomat 030). Glucose was measuredenzymatically.

Glucose, Na+, K+, and osmolality of the intestinal content. The animals were killed by intravenous injection of urethane, the tissues were removed, and the content of jejunum, ileum,or colon was emptied into centrifuge tubes. After centrifugationat 5,000 rpm at 4°C for 20 min, samples were taken from the supernatantand tested for Na⁺, K⁺, glucose, and osmolality as describedabove.

BBMV preparation. The small and large intestines were rinsed with ice-cold saline solution and opened longitudinally. The mucose was scrapedoff with a glass slide, wrapped in aluminum foil, frozen in liquidnitrogen, and kept at $-$ 80°C untiluse.

BBMV were isolated from either jejunum or ileum as described by Peral et al. (12). Briefly, the mucose was thawed in a buffercontaining (in mM) 100 mannitol, 2 HEPES-Tris (pH 7.1), 0.2 phenylmethylsulfonyl-fluoride(PMSF), 0.5 DL-dithiothreitol, and 0.2 benzamidine, homogenizedin a Waring blender (model 32 BL80) at high speed for 30 s andfiltered through a Buchner funnel. MgCl₂ was added to the homogenateto a final concentration of 10 mM. The suspension was stirredfor 20 min and then centrifuged at 3,000 g for 15 min. The plasmamembranes retained in the supernatant were collected by centrifugationat 30,000 g for 30 min. The resultant pellet was suspended ina pH 7.4 buffer consisting of (in mM) 100 mannitol, 2 HEPES-Tris,and 0.1 MgSO₄. This suspension was homogenized with 50 up-downstrokes with a glass-Teflon homogenizer, brought up to 35-40 mlwith the same buffer, and centrifuged at 30,000 g for 30 min.The final pellet, containing the purified BBMV, was suspendedin the loading buffers as described above. The final suspensionwas homogenized by passing the suspension through 25- and 28-gaugeneedles. All the steps were carried out at 4°C.

BBMV were isolated from the colonic mucose, by the method described by Harig et al. (9), using Mg²⁺ precipitation instead of Ca²⁺ precipitation as described in Calonge et al. (3). Briefly,the mucose was defrosted in a solution (14 ml/g) containing (inmM) 50 mannitol, 0.2 PMSF, 0.5 DL-dithiothreitol, 0.2 benzamidine,and 2 HEPES-Tris, pH 7.0; homogenized with a Ystral Politron atsetting 4 for 90 s, and filtered through a nylon gauze. MgCl₂,at a final concentration of 10 mM, was added to the homogenateand stirred for 20 min. The suspension was centrifuged at 1,000g for 10 min, the resultant supernatant was centrifuged at 39,000g for 20 min, and the resultant pellet was suspended in appropriateloading buffers. The suspension was homogenized with 20 up-downstrokes with a glass-Teflon dounce homogenizer and centrifugedat 39,000 g for 30 min. The pellet was resuspended in the loadingbuffers described above. The isolated apical membranes were madehomogenous by passing them through a 25- and a 26-gauge needleseveral times; they were stored in liquid nitrogen until use.All the steps were carried out at 4°C.

Protein was measured by the method of Lowry et al. (13) using albumin as thestandard.

Uptake studies. ²²Na⁺ or $alpha$ -[D-¹⁴C]MG uptake was measured at 25°C by a rapid filtration technique as described (4). Briefly BBMV were left tostand at room temperature (~25°C) for 10 min. Timed incubationsat room temperature were initiated by adding 10 µl of suspendedmembrane vesicles to 90 µl of uptake buffer (100-150 µg of protein/100µl uptake buffer). The composition of the uptake buffers is givenabove. After designated periods of time, uptake was terminatedby the addition of 2.5 ml of an ice-cold stop solution of thesame composition as that of the intravesicular buffer. The sampleswere immediately filtered under vacuum through a 0.45-µm poresize Millipore filter prewetted with the stop buffer. Filterswere further washed twice with 5 ml of ice-cold stop solution,dissolved in 5 ml of Ready-Protein (Beckman) scintillation fluid,and radioactivity was determined by liquid scintillation spectrometry.Nonspecific isotope binding to the filters was determined separatelyby adding stop solution to the vesicles before addition of uptakebuffer and subtracted from the total radioactivity of each sample.All experiments were done intriplicate.

Materials. ²²Na⁺ or $alpha$ -[D-¹⁴C]MG were purchased from Amersham. Valinomycin, AVT, aldosterone, phlorizin, and all the salts used in the currentstudy were obtained from Sigma Chemical. HOE-694 was a gift fromDr. M.Donowitz.

Calculations and statistics. Vertical bars in Figs. 1-5 represent SE; they are absent when they are less than symbol height. Results are expressed as means± SE. Statistical significance was evaluated by Dunnett's test.

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Fig. 1. Plasma aldosterone concentration plotted vs. the duration of Na⁺ depletion. Aldosterone was measured as explained in MATERIALS AND METHODS. Data are the mean values ± SE of 4 animals. **P < 0.01 compared with commercial diet (zero time). The data at time 15 days have been taken from a previous report (7).

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Fig. 2. Adaptation to a low-Na⁺ diet and sodium/hydrogen exchange (NHE) activity in brush-border membrane vesicles (BBMV) isolated from chicken intestine. Na⁺ uptake was measured in the presence (5.5_i/7.5_o) and absence (5.5_i/5.5_o) of a proton gradient, during 1 min for jejunum (top) and ileum (middle) and 5 min in colon (bottom; time of peak overshoot values). The composition of the intra- and extravesicular buffers are given in MATERIALS AND METHODS. The concentration of HOE-694 was 50 µM. When tested, the vesicles were preincubated with the inhibitor for 12 min. NHE activity (1st

): Na⁺ uptake measured in the presence of a pH gradient minus that measured in the absence of a pH gradient. NHE2 activity ( $black-triangle$ ): pH gradient-dependent Na⁺ uptake sensitive to HOE-694. NHE3 activity (2nd

): pH gradient-dependent Na⁺ uptake insensitive to HOE-694. Data are mean values ± SE of 4 separate membrane vesicle preparations. *P < 0.05, **P < 0.001, compared with high-Na⁺ diet (zero time).

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Fig. 3. Adaptation to a low-Na⁺ diet and Na⁺-sugar cotransport activity in BBMV isolated from chicken intestine. $alpha$ -Methyl-glucopyranoside ( $alpha$ -MG) uptake into BBMV was measured in the presence of an inwardly directed electrochemical Na⁺ gradient, with or without 0.25 mM phlorizin, over 30 s for jejunum and ileum and 1 min for the colon (time of the peak overshoot values). Electrical membrane potential was created by an outwardly directed K⁺ gradient in the presence of valinomycin. An inside directed Na⁺ gradient was created by the addition of 50 mM Na⁺ to the extravesicular buffer. The intravesicular buffer was made nominally Na⁺ free. The data represent the Na⁺-dependent, phlorizin-sensitive sugar uptake (SGLT-1 activity), which is the total sugar uptake minus that measured in the presence of phlorizin. Data are mean values ± SE of 4 separate membrane vesicle preparations. **P < 0.001 compared with high-Na⁺ diet (zero time).

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Fig. 4. Effect of either aldosterone (open bars) or arginine vasotocin (AVT; hatched bars) on NHE activity in BBMV isolated from chicken intestine. The ileum (top) and colon (bottom) were incubated in the absence (control; solid bars) and presence of either 0.5 µM aldosterone or 0.5 µM AVT for 3 h, and BBMV were prepared thereafter. Other details as in Fig. 2. Data are mean values ± SE of 3 separate membrane vesicle preparations. *P < 0.05, **P < 0.001 compared with tissues not exposed to hormones.

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Fig. 5. Effect of either aldosterone (open bars) or AVT (hatched bars) on SGLT-1 activity in BBMV isolated from chicken intestine. The jejunum, ileum and colon were incubated in the absence (control; solid bars) and presence of either 0.5 µM aldosterone or 0.5 µM AVT for 3 h, and BBMV were prepared thereafter. Other details as in Fig. 3. Data are mean values ± SE of 3 separate membrane vesicle preparations. **P < 0.001 compared with tissues not exposed to hormones.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Adaptation to a low-Na+ diet and plasma and intestinal fluid parameters. Plasma aldosterone levels increased nearly hyperbolically with the duration of the Na⁺ depletion from 13 to 170 pg/ml, with a half-time close to 1 day(Fig. 1). The plasma levels of either sodium or glucose or osmolalitywere not affected by the treatment (Table 1).

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Table 1. Plasma and intestinal fluid parameters vs. the duration of NaCl depletion

After 12-h adaptation to a low-Na⁺ diet, the K⁺ concentration in the luminal fluid of the three intestinal regions was increased(see Table 1). The treatment also increased glucose concentrationin the intestinal content, whereas that of Na⁺ was decreased until values were undetectable (see Table 1).Intestinal fluid osmolality did not change in the small intestine,and it was decreased in the colon (see Table 1). Although thefood delivery was neither measured nor controlled, it was notedthat the animals fed on a low-Na⁺ diet tended to eat less (the amount of food remaining in thecontainers was always greater than that in those containing high-Na⁺ diet). However, a decrease in food intake would not explain themeasured increase in both K⁺ and glucose concentrations in the intestinal content; hence theseobservations suggest that intestinal transport activity was changedby thetreatment.

Na+ content in the diet and Na⁺ uptake into BBMV isolated from chick intestine. Na⁺ uptake into chicken intestinal BBMV was measured in the presence and absence of an inwardly directed pH gradient and undermembrane voltage-clamped conditions (equal internal and externalpotassium concentrations plus valinomycin). The contribution ofeither NHE2 or NHE3 to total NHE activity was determined usingthe amiloride-related drug HOE-694 (50 µM), which in rat and rabbithas higher sensitivity to NHE2 (K_i, 5 µM) than to NHE3 (K_i, 650µM) (5, 16). Therefore, 50 µM HOE-694 will inhibit NHE2 activityand will have no significant effect on NHE3activity.

The results revealed (Fig. 2) that jejunal NHE activity was not modified by Na⁺ depletion, whereas both ileal and colonic NHE activity increasedwith the time of the duration of treatment, and the increase wasdue to increased NHE2 activity. NHE3 activity was notmodified.

Time-dependent effect of Na+ depletion on SGLT-1 activity in BBMV isolated from chicken intestine. Sugar uptake into intestinal BBMV was measured in the presence of an inwardly directed electrochemical Na⁺ gradient, with or withoutphlorizin.

Feeding with a low-Na⁺ diet significantly decreased SGLT-1 activity in jejunum, ileum, and colon (Fig. 3). The downregulationof SGLT-1 activity reached a plateau at 2 days of treatment. Low-Na⁺ diet did not affect the phlorizin-insensitive sugar transportcomponent (data notshown).

Effect of either aldosterone or AVT on SGLT-1 and NHE activities in BBMV isolated from the jejunum, ileum, and colon. BBMV were isolated from jejunum, ileum, and colon after 3-h incubation with or without 0.5 µM aldosterone or 0.5 µM AVT. Sugaruptake and Na⁺ uptake into BBMV were measured as indicatedabove.

The results show (Figs. 4 and 5) that aldosterone and AVT affected intestinal Na⁺-linked transport systems activity differently. Thus aldosteroneincreased ileal and colonic NHE activity, via an increase in NHE2activity. Jejunal NHE activity was not modified by aldosterone(data not shown). On the other hand, intestinal NHE activity wasnot significantly modified byAVT.

Small and large intestinal SGLT-1 activity was not modified by the in vitro exposure of the tissues to aldosterone (Fig. 5),but it was stimulated byAVT.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The current results show for the first time that AVT stimulates intestinal SGLT-1 activity and corroborate our previous view(6) that aldosterone does not mediate the effects of Na⁺ depletion on intestinal SGLT-1activity.

The following observations suggest that aldosterone regulates ileal and colonic NHE2 activity, but it does not mediate thedecrease in intestinal SGLT-1 activity induced by Na⁺ depletion: 1) incubation of the intestine with aldosterone increasedileal and colonic NHE2 activity as it does Na⁺ depletion; 2) SGLT-1 activity was decreased by Na⁺ depletion but it was not affected by aldosterone; and 3) thetime course of the effect of Na⁺ depletion on plasma aldosterone levels is similar to that onNHE2 activity, but not to that on SGLT-1activity.

We (6) have suggested that, because Na⁺ depletion and dehydration increased plasma aldosterone levels and produced oppositeeffects on SGLT-1 activity, aldosterone does not regulate intestinalSGLT-1. As plasma AVT levels are increased by dehydration (1)and decreased by Na⁺ depletion (2), it was concluded (6) that AVT could be theregulator of intestinal SGLT-1. The current results corroboratethis hypothesis, because the incubation of the intestine withAVT increased small and large intestinal SGLT-1activity.

In our previous study (6) we also suggested that AVT regulates jejunal NHE activity because it was not affected by Na⁺ depletion, but it was increased by dehydration. However, thecurrent results show that neither aldosterone nor AVT significantlyaffected jejunal NHE activity. These results do not agree withprevious reports showing that AVT inhibits NHE3 activity in Madin-Darbycanine kidney cells transfected with NHE3 (10).

It could be concluded that, in the chick, 1) apical NHE2 activity in ileum and colon is regulated by aldosterone and 2) smalland large intestinal SGLT-1 activity is regulated by AVT. Thecurrent results, however, do not provide any clue to explain theincrease in jejunal NHE activity induced by dehydration. It couldbe another hormonal factor. The decrease in intestinal SGLT-1activity induced by Na⁺ depletion could be due either to a decrease in AVT secretion(2) or to the effect of Na⁺ content in the intestinal lumen on the expression of the SGLT-1.Thus Na⁺ depletion reduced Na⁺ concentration in the intestinal content until values were undetectable,and this decrease was accompanied by an increase in glucose concentrationin the intestinal content. Further investigation is required tocharacterize the molecular mechanisms underlying the changes inactivity of the transporters under study and to determine thelink between Na⁺ depletion and intestinal sugar transportactivity.

A collateral observation of the current study is that adaptation to a low-Na⁺ diet increased the K⁺ concentration in the luminal fluid of the three intestinal regions,indicating that the treatment stimulated intestinal potassiumsecretion, which agrees with previous observations in rat colon(8, 15).

Perspectives

The current results agree with the idea that the physiological role of the large intestinal amiloride-inhibitable Na⁺ absorption is to conserve NaCl and that of organic solute-Na⁺ cotransport is to conserve water (14) and suggest that thesmall intestine could also contribute to these homeostatic functions.Under Na⁺ depletion, both the extracellular fluid volume and osmolalityfall (11). Regulation of extracellular fluid volume requiresNa⁺ and water retention, and osmoregulation demands water excretionin a diluted urine. The increase in Na⁺/H⁺ exchange activity and the decrease in Na⁺-sugar cotransport activity, induced by the low-Na⁺ diet, will help to conserve Na⁺ and to excrete water, respectively. This will be achieved byincreasing the plasma levels of aldosterone, which increases Na⁺/H⁺ exchange activity, and by decreasing those of AVT, which wouldreduce SGLT-1 activity. On the other hand, the dehydration-inducedincrease in both Na⁺/H⁺ exchange activity and Na⁺-dependent sugar transport will help to conserve both Na⁺ and water, and, therefore, to maintain both extracellular fluidvolume and osmolality within acceptable limits. From a physiologicalpoint of view, it is an advantage that the two Na⁺-linked transport systems are regulated by a different hormone,which allows different regulation of each transporter accordingto the homeostatic demands of the organism. The potential physiologicalcontribution of large intestinal active organic solute cotransportcould be either to prevent the loss of sugar in the feces or tofacilitate it according to the homeostatic needs of theanimal.

	ACKNOWLEDGEMENTS

We thank F. Frieras for technicalhelp.

	FOOTNOTES

This work was supported by a grant from the Spanish Dirección General de Investigación Científica y Técnica PM99-0121.

Address for reprint requests and other correspondence: A. A. Ilundáin, Dept. Fisiología y Biología Animal, Facultad deFarmacia, C) Tramontana s/n, 41012 Sevilla, Spain (E mail: ilundain{at}cica.es).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 27 March 2000; accepted in final form 23 October 2000.

	REFERENCES

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