Variations in epithelial Na(+) transport and epithelial sodium channel localisation in the vaginal cul-de-sac of the brushtail possum, Trichosurus vulpecula, during the oestrous cycle.

The fluid in the vaginal cul-de-sac of the brushtail possum, Trichosurus vulpecula, is copious at ovulation when it may be involved in sperm transport or maturation, but is rapidly reabsorbed following ovulation. We have used the Ussing short-circuit current (Isc) technique and measurements of transcript and protein expression of the epithelial Na(+) channel (ENaC) to determine if variations in electrogenic Na(+) transport are associated with this fluid absorption. Spontaneous Isc (<20µAcm(-2) during anoestrus, 60-80µAcm(-2) in cycling animals) was inhibited by serosal ouabain. Mucosal amiloride (10µmolL(-1)), an inhibitor of ENaC, had little effect on follicular Isc but reduced luteal Isc by ~35%. This amiloride-sensitive Isc was dependent on mucosal Na(+) and the half-maximal inhibitory concentration (IC50)-amiloride (0.95µmolL(-1)) was consistent with ENaC-mediated Na(+) absorption. Results from polymerase chain reaction with reverse transcription (RT-PCR) indicate that αENaC mRNA is expressed in anoestrous, follicular and luteal phases. However, in follicular animals αENaC immunoreactivity in epithelial cells was distributed throughout the cytoplasm, whereas immunoreactivity was restricted to the apical pole of cells from luteal animals. These data suggest that increased Na(+) absorption contributes to fluid absorption during the luteal phase and is regulated by insertion of ENaC into the apical membrane of cul-de-sac epithelial cells.

Molecular and functional characterization of the cystic fibrosis transmembrane conductance regulator from the Australian common brushtail possum, Trichosurus vulpecula.

Unlike eutherian mammals, the colon of the Australian common brushtail possum, Trichosurus vulpecula, a metatherian mammal, is incapable of electrogenic Cl(-) secretion and has elevated levels of electrogenic Na(+) absorption, while the ileum secretes HCO (3) (-) rather than Cl(-). In eutherian mammals, the cystic fibrosis transmembrane conductance regulator (CFTR) is essential for both Cl(-) and HCO (3) (-) secretion and the regulation of Na(+) absorption. Therefore, we have sequenced possum (p)CFTR, described its distribution and characterized the properties of cloned pCFTR expressed in Fischer rat thyroid (FRT) cells. pCFTR (GenBank accession No. AY916796) has a 1,478 amino acid open reading frame, which has >90% identity with CFTR from other marsupials and >80% identity with non-rodent eutherian mammals. In pCFTR, there is a high level of conservation of the transmembrane and nucleotide binding domains although, with the exception of other marsupials, there is considerable divergence from other species in the R domain. FRT cells transfected with pCFTR express mature CFTR protein which functions as a small Cl(-) channel activated by cAMP-dependent phosphorylation. In whole-cell recordings it has a linear, time and voltage-independent conductance, with a selectivity sequence P(Br) > P(Cl) > P(I) > P(HCO)(3) >> P(Gluconate). pCFTR transcript is present in a range of epithelia, including the ileum and the colon. The presence of pCFTR in the ileum and its measured HCO (3) (-) permeability suggest that it may be involved in ileal HCO (3) (-) secretion. Why the possum colon does not secrete Cl(-) and has elevated electrogenic Na(+) absorption, despite the apparent expression of CFTR, remains to be determined.

Enhancing absorption of fluorescein and LHRH across hindgut epithelia in a marsupial, the common brushtail possum Trichosurus vulpecula.

We have identified differences in transport properties of intestinal epithelia in the marsupial brushtail possum, compared to eutherian mammals. To determine whether differences in its permeability to hydrophilic compounds also occur, the absorption of sodium fluorescein and luteinizing hormone releasing hormone (LHRH) was assessed in vitro and the ability of chemical enhancers and a metabolic inhibitor to promote their absorption investigated. The apparent permeability of colonic and caecal tissues to fluorescein and LHRH and transepithelial resistance (Rt) in the absence or presence of ethylenediamine tetra-acetic acid (EDTA), sodium deoxycholic acid (SDA), dithiothreitol (DTT), polyacrylic acids (PAA), or the inhibitor bacitracin were determined. The effects of SDA and/or DTT on adherent mucus and the release of lactate dehydrogenase (LDH) were also assessed. In the absence of treatment, both tissues had comparable amounts of adherent mucus, Rt and low permeabilities to fluorescein and LHRH. All chemical enhancers increased fluorescein permeability, but SDA at concentrations >0.5 mM also induced LDH release. DTT alone and in combination with SDA reduced the amount of adherent mucus. Bacitracin inhibited LHRH metabolism and increased LHRH permeability. These data indicate that the possum hindgut epithelium represents a significant barrier to the uptake of hydrophilic compounds, similar to that in eutherians.

An in situ single-pass perfusion model for assessing absorption across the intestinal mucosa of the brushtail possum.

AIM: To develop an in situ animal model for assessing absorption of molecules across the intestinal mucosa of possums. METHODS: A surgical preparation was used to perfuse known concentrations of reference compounds (fluorescein and luteinising hormone-releasing hormone; LHRH) through measured sections of selected regions (jejunum, caecum, proximal colon) of the intestinal tract of 19 possums, over a 2-h period. Plasma concentrations of the compounds, which were perfused either with or without co-administration of a permeation enhancer (sodium deoxycholic acid; SDA), were determined in the perfusion effluent, peripheral and in some instances in the pre-hepatic circulation by spectrofluorometry (fluorescein) or radioimmunoassay (LHRH). Pharmacokinetic parameters of both compounds in the possum were determined over a period of up to 4 h in a further 30 animals (fluorescein, n = 6; LHRH n = 24), from their plasma profiles following intravenous (I/V) administration of a bolus dose. RESULTS: In animals perfused with 25 mg/ml fluorescein (Perfusion Experiment (PE) 1), the mean plasma concentration was 2.8 (SE 0.12) microg/ml in post-hepatic blood samples. When possums were perfused with 2.5 mg/ml fluorescein and 7 microg/ml LHRH (PE 2), mean plasma concentrations were 0.3 (SE 0.01) and 7.8 (SE 1.64) microg/ml fluorescein and 0.1 (SE 0.02) and 6.3 (SE 0.45) ng/ml LHRH, in the absence and presence of permeation enhancer, respectively. There was a poor correlation between pre-hepatic and post-hepatic concentrations. CONCLUSIONS: The single-pass in situ perfusion technique provided a useful model for investigating basic information on the absorption of biocontrol agents across the intestinal tract of possums, but had limitations that must be recognised.

A glucocorticoid-induced Na+ conductance in human airway epithelial cells identified by perforated patch recording.

The perforated patch recording technique was used to investigate the effects of dexamethasone (0.2 microm, 24-30 h), a synthetic glucocorticoid, on membrane conductance in the human airway epithelial cell line H441. Under zero current clamp conditions this hormone induced amiloride-sensitive depolarization of the membrane potential (V(m)). Lowering external Na(+) to 10 mm by replacing Na(+) with N-methyl-d-glucammonium (NMDG(+)) also hyperpolarized the dexamethasome-treated cells, whilst replacing Na(+) with Li(+) caused a small depolarization. Although V(m) was insensitive to amiloride in control cells, NMDG(+) substitution caused a small hyperpolarization and so an amiloride-insensitive cation conductance is present. Replacing Na(+) with Li(+) had no effect on V(m) in such cells. Voltage clamp studies of dexamethasone-treated cells showed that the amiloride-sensitive component of the membrane current reversed at a potential close to the Na(+) equilibrium potential (E(Na)), and replacing Na(+) with K(+) caused a leftward shift in reversal potential (V(Rev)) that correlated with the corresponding shift in E(Na). Lowering [Na(+)](o) to 10 mm, the concentration in the pipette solution, by substitution with NMDG(+) shifted V(Rev) to 0 mV, whilst replacing Na(+) with Li(+) caused a rightward shift. Exposing dexamethasone-treated cells to a cocktail of cAMP-activating compounds (20 min) caused a approximately 2-fold increase in amiloride-sensitive conductance that was associated with no discernible change in ionic selectivity and an 18 mV depolarization. Dexamethasone thus induces the expression of a selective Na(+) conductance with a substantial permeability to Li(+) that is subject to acute regulation via cAMP. These data thus suggest that selective Na(+) channels underlie cAMP-regulated Na(+) transport in airway epithelia.

Inhibition of proteolysis in luminal extracts from the intestine of the brushtail possum.

The proteolytic activity of luminal extracts from five regions (duodenum, jejunum, ileum, caecum and colon) of the brushtail possum intestine towards bovine serum albumin (BSA) and human luteinizing hormone releasing hormone (LHRH) was investigated. There were no significant differences in degradation rates between fresh and previously frozen extracts from any region of the possum intestine. The inhibition of degradation of BSA by luminal extracts from two regions (jejunum and ileum) and of LHRH from four regions (jejunum, ileum, caecum and colon) was evaluated. Soybean trypsin-chymotrypsin inhibitor (SBTI), sodium deoxycholate, Carbopol 934P, bacitracin and bestatin significantly inhibited the degradation of both LHRH and BSA (P < 0.05). SBTI almost totally inhibited the proteolysis of BSA and the peptidolysis of LHRH in extracts from the small intestine. This finding suggests that serine proteases such as chymotrypsin are responsible for the protein and peptide degradation in luminal extracts. It is concluded that including serine protease inhibitors in a formulation may enhance oral delivery of bioactive peptides and proteins to possums.

Enzymatic degradation of luteinizing hormone releasing hormone (LHRH) by mucosal homogenates from the intestine of the common brushtail possum (Trichosurus vulpecula).

The peptidolytic activity of fresh and frozen mucosal homogenates from five regions (duodenum, jejunum, ileum, caecum and colon) of possum intestine from Trichosurus vulpecula towards human Luteinizing Hormone Releasing Hormone (LHRH) was investigated. The rank of order of specific peptidolytic activity of the mucosal homogenates was jejunum > ileum > caecum> duodenum = colon, with a 3 to 4 fold difference between the least and the most active segment in both frozen and fresh samples. The formation of peptides LHRH (1-3), LHRH (1-4) and LHRH (1-5) suggest endopepetidase-24.18, endopeptidase-24.15 and angiotensin converting enzyme (ACE) might be responsible for the peptide degradation in mucosal homogenates. The inhibition of LHRH degradation by mucosal homogenates was evaluated in four regions (jejunum, ileum, caecum and colon) of possum intestine. Ethylenediaminetetraacetic acid (EDTA, 5 mM), sodium deoxycholate (SDA, 10 mM) and bacitracin (3.5 or 9 mM) inhibited the degradation of LHRH in mucosal homogenates from small intestine and hindgut. However, the serine protease inhibitor, soybean trypsin-chymotrypsin inhibitor (SBTI), did not prevent degradation of LHRH. It is concluded that combining peptides with inhibitors may enhance oral delivery of bioactive peptides or proteins to possums.

Protein and peptide degradation in the intestine of the common brushtail possum (Trichosurus vulpecula).

A protein (bovine serum albumin: BSA) and a peptide (luteinizing hormone releasing hormone: LHRH) were used to evaluate proteolytic activity in the intestine of common brushtail possums (Marsupiala, Trichosurus vulpecula). Luminal and mucosal extracts were isolated from the duodenum, jejunum, ileum, caecum, proximal colon and distal colon, their protein content assessed and specific activities in metabolising LHRH and BSA determined in vitro. The degradation of LHRH by luminal extracts was compared with that by the pancreatic enzymes, chymotrypsin, trypsin, and elastase. The protein concentration (microg x mg-1) of mucosal extract in the duodenum was higher ( P<0.05) than in the proximal colon, but that of luminal extracts did not differ significantly between regions. Proteolytic activity of luminal extracts was greater ( P<0.01) in the jejunum and ileum than in the hindgut. In the small intestine, proteolytic activity of luminal enzymes far exceeded that of mucosal enzymes ( P<0.05). All three pancreatic enzymes hydrolysed LHRH, but chymotrypsin had the greatest activity. This study has demonstrated that, in possums, proteolysis occurs primarily in the small intestine through luminal enzymes, with chymotrypsin playing a major role. The possum hindgut contributes little to the metabolism of peptides and proteins, identifying it as a potential site to target for their absorption following oral delivery.

Electrogenic ion transport in the intestine of the Australian common brushtail possum, Trichosurus vulpecula: indications of novel transport patterns in a marsupial.

In this study, electrogenic ion transport in the intestine of the Australian common brushtail possum, Trichosurus vulpecula was investigated. In the ileum, a Na(+)-dependent, phloridzin- and amiloride-insensitive short-circuit current ( Isc) was present. Mucosal glucose stimulated a further phloridzin-sensitive, dose-dependent increase in Isc. A Na(+)-dependent, ouabain-sensitive Isc was also present in the caecum and colon. In the proximal and distal colon, amiloride (100 micro mol l(-1), mucosal) inhibited this Isc by 81+/-4% and 65+/-3%, respectively and the Ki for amiloride (approximately 1 micro mol l(-1)) was consistent with the inhibition of a classical epithelial Na(+) channel. In the caecum, 50% of the Isc was inhibited by amiloride (100 micro mol l(-1), mucosal). The amiloride-insensitive Isc in the colon was not due to electrogenic Cl(-) secretion, as serosal bumetanide (100 micro mol l(-1)) had no effect on the Isc. Furthermore, the secretagogues forskolin (10 micro mol l(-1)), carbachol (100 micro mol l(-1)) and dibutyryl-cAMP or dibutyryl-cGMP (100 micro mol l(-1)) did not stimulate electrogenic Cl(-) secretion by the colon. These results indicate that the transport properties of the hindgut of the possum differ significantly from those of eutherian mammals and may be associated with different functions of the hindgut of possums when compared to eutherian mammals.

Aldosterone does not regulate amiloride-sensitive Na(+) transport in the colon of the Australian common brushtail possum, Trichosurus vulpecula.

Plasma aldosterone concentrations and the magnitude of amiloride-sensitive Na(+) transport in the proximal and distal colon of newly caught wild possums, and of possums maintained on either low or high Na(+) diets, were determined to evaluate their role in the regulation of salt content of faeces in common brushtail possums. Wild animals had a plasma aldosterone concentration of 439+/-115 pmol l(-1) and high levels of amiloride-sensitive Na(+) transport in both the proximal and distal colon. Animals maintained on a low Na(+) diet for 14 days excreted very little Na(+) in the urine and had an elevated aldosterone concentration (840+/-246 pmol l(-1)), but levels of amiloride-sensitive Na(+) transport in the proximal and distal colon were similar to those in wild animals. Conversely, while provision of a high Na(+) diet (7 days or 14 days) resulted in increased urinary Na(+) excretion and a fall in aldosterone (approximately 250 pmol l(-1)), there was no reduction in the amount of amiloride-sensitive Na(+) transport in either the proximal or distal colon. These data strongly indicate that aldosterone does not regulate amiloride-sensitive Na(+) transport in the colon of possums and that the colon is not involved in the regulation of salt content of the faeces in this species.

HCO3- potentiates the cAMP-dependent secretory response of the human distal colon through a DIDS-sensitive pathway.

We used the Ussing short-circuit technique to investigate the role of HCO3- in the adenosine 3',5'-cyclic monophosphate (cAMP)-dependent secretory response of the human distal colon. In HCO3(-)-free 4-(2-hydroxyethyl)-1-piperazineethanesulphonic acid (HEPES)-Ringer's, forskolin (10 mumol l-1 mucosal and serosal) evoked a sustained increase in short-circuit current (Isc) (delta Isc = 24 +/- 3 microA cm-2, n = 57). However, this was only 25% of the forskolin-stimulated Isc response in HCO3(-)-Ringer's (delta Isc = 84 +/- 8 microA cm-2, n = 57). The reduced response to forskolin in HCO3(-)-free HEPES-Ringer's was not due to inhibition of the secretory mechanism by HEPES, as replacing HCO3- with a different buffer, N-tris[hydroxymethyl)methyl-2-aminoethanesulphonic acid (TES), had a similar effect and inclusion of HEPES in the HCO3(-)-Ringer's did not reduce the secretory response. Similarly, it was not due to an indirect modulation of electrogenic Cl- secretion, as the forskolin-stimulated bumetanide-sensitive Isc was comparable in the two Ringer's. Rather it was due to the activation of a HCO3(-)-dependent Isc which was inhibited by serosal 4,4'-diisothiocyano-stilbene-2,2'-disulphonate (DIDS). This DIDS-sensitive Isc was not inhibited by acetazolamide, but it was inhibited by the replacement of bathing solution Cl- with gluconate, suggesting a role for a Na(+)-dependent Cl-/HCO3- exchanger in the cAMP-dependent secretory response of the human distal colon.

The molecular basis of renal tubular transport disorders.

Sodium and water homeostasis are key to the survival of organisms. Reabsorption of sodium and water occurs throughout the tubule structure of the nephron, the basic functional unit of the kidney, by various transport mechanisms. Altered transport protein function can lead to renal tubular disorders resulting in metabolic alkalosis, hypokalemia, hypertension, and decreased capacity to concentrate urine, for instance. However, recent advances in molecular physiology, molecular genetics and expression cloning systems have aided in unraveling the molecular basis of some renal tubular disorders. This review will examine the molecular basis of Bartter's syndrome, Gitelman's syndrome, Liddle's syndrome, and autosomal nephrogenic diabetes insipidus. An understanding of the molecular basis of these disorders of the human kidney can give us a better understanding of basic renal function of lower mammals and other vertebrates.

Effect of somatostatin on electrogenic ion transport in the duodenum and colon of the mouse, Mus domesticus.

In this study, we have used the mouse intestine and the Ussing short circuit technique to compare the effects and mechanism of action of somatostatin (SST, 0.1 microM) on cAMP- and Ca(2+)-mediated ion secretion in the duodenum and colon of the Swiss-Webster mouse. The cAMP-dependent secretagogues, prostaglandin E(2) (1 microM) and dibutyryl-cAMP (150 microM) increased short circuit current (I(sc)) in both regions, but only the colonic response was inhibited by SST. This inhibition was independent of enteric nerves, suggesting a direct action on the epithelial cells. The Ca(2+)-dependent secretagogue carbachol (10 microM) stimulated a transient increase in I(sc) in both intestinal segments. In the duodenum, SST partially inhibited this increase in I(sc) and both the responses to carbachol and SST were independent of enteric nerves. In the colon, while SST inhibited the carbachol induced increase in I(sc), pre-treatment with tetrodotoxin (750 nM) profoundly inhibited the carbachol induced increase in I(sc), thus markedly reducing the inhibitory effect of SST. This indicates an involvement of the enteric nervous system in the response to carbachol and the action of SST in the colon. These data indicate marked regional differences within the mouse intestine of the effects of SST on ion secretion and demonstrate different mechanisms of action of SST in the duodenum and colon.

Controlled release opportunities for oral peptide delivery in aquaculture.

Over the last decade, fish supplies for human consumption have reached over 100 million tons. Due to overfishing, future increases in demand can only be met from the aquaculture industry. This will require increased research in areas such as the control and manipulation of fish reproduction. There is increasing interest in the oral delivery of peptides that control gamete reproduction. However, compared to mammalian species, little is known about the barriers to peptide delivery and methods to improve such delivery. The three major barriers to peptide delivery are the enzymatic barriers sourced from the host luminal and membrane bound peptidases, the immunological cells present within both the enterocytes and underlying connective tissue and the physical barrier of the epithelial cells. Furthermore, the anatomy and physiology of the gastrointestinal tract of these species are markedly different when compared to higher vertebrates and therefore must be considered when designing appropriate delivery systems. Research to date has focused on the oral delivery and subsequent pharmacodynamic responses to the peptides associated with growth and reproduction. However, minimal work has been undertaken to overcome the identified barriers and therefore any future investigations need to attend to these obstacles before the oral delivery of bioactive peptides can become a commercial reality.

1-EBIO stimulates Cl- secretion by activating a basolateral K+ channel in the mouse jejunum.

We investigated the effects of 1-ethyl-2-benzimidazolinone (1-EBIO) on ion transport in the mouse jejunum through the use of the short-circuit (Isc) current technique and the application of the patch-clamp technique to isolated jejunal crypts. In HCO3- Ringer's, 1-EBIO stimulated a dose-dependent (EC50 964 micromol/l), bumetanide-sensitive increase in Isc consistent with stimulation of Cl- secretion. In contrast, in Cl(-)-free HCO3-Ringer's containing glucose, 1-EBIO (500 micromol/l) did not increase the phloridzin (100 micromol/l) sensitive Isc, suggesting that electrogenic Na+ absorption was unaltered. Measurement of the membrane potential (Vm) with the perforated-patch technique indicated that in isolated crypts, 1-EBIO caused a reversible hyperpolarization of Vm and an increase in the change in Vm associated with step changes in bath K+, consistent with an increase in K+ conductance. In on-cell patch experiments with KCI Ringer's in the patch pipette and crypts bathed with NaCl Ringer's, 1-EBIO (500 micromol/l) increased the open probability (NPo; 0.01+/-0.01 to 0.45+/-0.11, n=7) of an inwardly rectified intermediate conductance (g) channel. In inside-out patches with KCl Ringer's in the patch pipette and KCI Ringer's containing 100 nmol/l Ca2+ in the bath, the current-voltage relationship of the channel was inwardly rectified (g of 10 and 52 pS at -Vp of 100 and -100 mV, respectively) and reversed at 0 mV (n=5). Replacement of bath K+ with Na+ shifted the reversal potential toward the equilibrium potential for K+. In the presence of 1-EBIO, reducing the bath Ca2+ from 200 nmol/l to nominally Ca(2+)-free conditions decreased NPo from 0.90+/-0.27 to 0.07+/-0.03 (n=3). We conclude that in the mouse jejunum, I-EBIO does not stimulate electrogenic Na+ absorption. It does, however, stimulate secretion primarily through the activation of a basolateral, intermediate conductance Ca(2+)-sensitive K+ channel.

Ion channels in isolated mouse jejunal crypts.

The patch-clamp technique was used to characterise the ion channels in cells located in the mid region of mouse jejunal crypts. Six different channels were seen. A large outwardly rectified K+ channel (BK) (conductance, g at 0 mV = 92 +/- 6 pS), which was highly selective for K+ [PK+ (1) > PRb+ (0.6) >> PCs+ (0.09) approximately PNa+ (0.07) > PLi+ (0.04)], had a low, voltage-independent open probability (Po) in the on-cell (O/C) configuration and appeared in 66% of the patches. In inside-out (I/O) patches, this channel had a linear current/voltage (I/V) relationship (g = 132 +/- 3 pS), Po was voltage dependent and it was blocked by cytoplasmic Ba2+ (5 mmol/l). An intermediate K+ channel (IK) which was present in 49% of O/C patches, had a linear I/V (g = 38 +/- 3 pS), ran-down in O/C patches, and was not seen in I/O patches. A number of smaller channels (SC) with conductances ranging from 5 to 20 pS were seen in 16% of O/C patches. Also present in the basolateral membrane were a Cl- channel (ICOR) and a nonselective cation channel (NSCC). These channels were only seen in I/O patches. ICOR had an outwardly rectified conductance (g at 0 mV = 36 +/- 2 pS), its Po was independent of voltage and unaffected by variations in cytoplasmic Ca2+ (100 nmol/l to 1 mmol/l) or ATP (0-1 mmol/l). The NSCC had a linear conductance (20 +/- 1 pS), its Po increased with depolarisation and elevation of cytoplasmic [Ca2+] (> or = 10 micromol/l), but was reduced by cytoplasmic ATP. None of the basolateral channels described here were activated by cAMP-dependent secretagogues, although a Cl- conductance was activated. This cAMP-dependent Cl- conductance was distinct from the basolateral Cl- channel and thus is most likely located in the apical membrane.

Villus and crypt cell composition in the secreting mouse jejunum measured with x-ray microanalysis.

The response of the villus and crypt cells of the mouse jejunum to secretagogues has been assessed through measurements of cellular composition with x-ray microanalysis. In nonstimulated tissues the Na concentration ([Na]c) of the crypt cells was significantly less, and the K ([K]c) and Cl ([Cl]c) concentrations were significantly greater, than that of the villus cells. There was also a decreasing gradient of [Na]c and increasing gradient of [K]c from the villus tip to crypt base due to a greater number of cells with a high [Na]c and low [K]c in the upper regions of the villi. Theophylline (10 mmol L-1) stimulated a sustained increase in bumetanide sensitive short circuit current (Isc) and significantly decreased the [Na]c of the villus cells. Similar, but smaller changes were seen in the crypt cells. Changes in villus cell [Na]c reflected a reduction in the number of cells with a high [Na]c. Inhibition of the apical Na/H exchanger (1 mmol L-1 amiloride) had little effect on basal Isc and the subsequent addition of theophylline increased Isc to a comparable extent as seen without amiloride. However, after amiloride treatment the only change in cellular composition was a reduction in the [Cl]c of both crypt and villus cells, suggesting that both regions are involved in the secretory response. These data suggest that the dominant response of the jejunum to secretagogues is an inhibition of Na absorption via Na/H exchange in the villi and the secretory response is distributed throughout the crypt/villus axis.

Effects of voltage clamping on epithelial cell composition in toad urinary bladder studied with x-ray microanalysis.

Toad urinary bladder epithelial cells were incubated in Na Ringer's with the serosal surface of the epithelium clamped at either +50 mV, 0 mV (short-circuited) or -50 mV with respect to the mucosal surface. Following incubation, portions of tissue were coated with an external albumin standard and rapidly frozen. Cryosections were freeze-dried and cell composition determined by x-ray microanalysis. Cell water and ion contents were unaffected when tissues were short-circuited rather than clamped close to their open-circuit potential difference (+50 mV). Incubation with vasopressin at +50 mV, and under short-circuit conditions, caused Na uptake without cell swelling or gain in Cl. Clamping at -50 mV resulted in uptake of water and ions, with considerable variation from cell to cell. These variations in cell composition were exacerbated by vasopressin. The greater the increase in water content, the greater the rise in cell Cl. However, there was no consistent pattern to the associated changes in cation contents. Most cells gained some Na. In some cells, this gain was accompanied by an increase in K. In others, the gain of Na was predominant and cell K content actually fell. At -50 mV with ouabain, many of the cells also gained water. As was found in our earlier study with ouabain under short circuit conditions (Bowler et al., 1991), there was considerable variation in the extent of the Na gain and K loss; some cells were largely depleted of K while in others the K content remained relatively normal. These results indicate differences between granular cells in the availabilities in the plasma membranes of ion pathways, either as a consequence of differences in the numbers of such pathways or in their control.

Cell Cl and transepithelial na transport in toad urinary bladder.

Relationships between short-circuit current (Isc), cell Cl and the mechanism(s) of Cl accumulation in toad bladder epithelial cells were investigated. In serosal Cl-free gluconate Ringer, 80% of the cell Cl (measured by x-ray microanalysis) was lost over 30-60 min with an associated decrease in cell water content. concomitantly, Isc fell to 20% of its initial value within 10 min but then recovered to 45% of its initial value despite continued Cl loss. With the reintroduction of Cl, cell Cl and Isc both recovered within 10 min. Serosal SITS (4-acetamido-4'-isothiocyano-stilbene-2,2'-disulfonate; 0.5 mM) plus bumetanide (0.1 mM), did not prevent the fall in Isc or the loss of cell Cl in gluconate medium, although they did inhibit subsequent recovery of Isc in this medium. They also prevented the recovery of Isc in Cl medium but not the reaccumulation of Cl by the cells. Although SITS and bumetanide did not prevent the loss or recovery of Cl, they modified the pattern of the ion changes. In their absence, changes in cellular Cl were twice that of the changes in measured cellular cations implicating basolateral Cl/HCO3 exchange in Cl movement. With SITS plus bumetanide present, changes of similar magnitude in Cl were associated with equivalent changes in cation, consistent with the inhibition of Cl/HCO3 exchange.

Potassium conductances in tracheal epithelium activated by secretion and cell swelling.

Increased basolateral membrane K conductance accompanies stimulation of Cl secretion across canine trachea. To assess the K conductance properties, we permeabilized the apical membranes with amphotericin B and monitored the current and conductance caused by K flow across the basolateral membranes. Under basal unstimulated conditions, two K conductances could be distinguished by blockers. One was inhibited only by barium; the other was sensitive also to quinidine and lidocaine. The permeabilities of the basal conductance pathways to K and Rb were similar (PK/PRb approximately equal to 1.5). The secretory agonist, epinephrine, selectively increased the quinidine-insensitive conductance, implicating it in the Cl secretory response. Cell swelling induced a third conductance with a low permeability to Rb (PK/PRb approximately equal to 10) that was quinidine sensitive. In tissues not treated with amphotericin, neither quinidine nor Rb-for-K replacement inhibited transepithelial Cl secretion. Thus neither of the quinidine-sensitive K conductances (basal or swelling induced) contribute to the increase in basolateral K conductance during Cl secretion. Cell shrinkage inhibited all three conductances and secretion, suggesting that the initial priority of the cell is volume regulation.