Sugar uptake, metabolism, and chloride secretion in the rectal gland of the spiny dogfish Squalus acanthias.

The rectal gland of the spiny dogfish Squalus acanthias secretes a salt solution isosmotic with plasma that maintains the salt homeostasis of the fish. It secretes salt against an electrochemical gradient that requires the expenditure of energy. Isolated rectal glands perfused without glucose secrete salt, albeit at a rate about 30% of glands perfused with 5 mM glucose. Gradually reducing the glucose concentration is associated with a progressive decrease in the secretion of chloride. The apparent Km for the exogenous glucose-dependent chloride secretion is around 2 mM. Phloretin and cytochalasin B, agents that inhibit facilitated glucose carriers of the solute carrier 2 (Slc2) family such as glucose transporter 2 (GLUT2), do not inhibit the secretion of chloride by the perfused rectal glands. Phloridzin, which inhibits Slc5 family of glucose symporters, or α-methyl-d-glucoside, which competitively inhibits the uptake of glucose through Slc5 symporters, inhibit the secretion of chloride. Thus the movement of glucose into the rectal gland cells appears to be mediated by a sodium-glucose symporter. Sodium-glucose cotransporter 1 (SGLT1), the first member of the Slc5 family of sodium-linked glucose symporters, was cloned from the rectal gland. No evidence of GLUT2 was found. The persistence of secretion of chloride in the absence of glucose in the perfusate suggests that there is an additional source of energy within the cells. The use of 2-mercapto-acetate did not result in any change in the secretion of chloride, suggesting that the oxidation of fatty acids is not the source of energy for the secretion of chloride. Perfusion of isolated glands with KCN in the absence of glucose further reduces the secretion of chloride but does not abolish it, again suggesting that there is another source of energy within the cells. Glucose was measured in the rectal gland cells and found to be at concentrations in the range of that in the perfusate. Glycogen measurements indicated that there are significant stores of glucose in the rectal gland. Moreover, glycogen synthase was partially cloned from rectal gland cells. The open reading frame of glycogen phosphorylase was also cloned from rectal gland cells. Measurements of glycogen phosphorylase showed that the enzyme is mostly in its active form in the cells. The cells of the rectal gland of the spiny dogfish require exogenous glucose to fully support the active secretion of salt. They have the means to transport glucose into the cells in the form of SGLT1. The cells also have an endogenous supply of glucose as glycogen and have the necessary elements to synthesize, store, and hydrolyze it.

AMP-activated protein kinase and adenosine are both metabolic modulators that regulate chloride secretion in the shark rectal gland ( Squalus acanthias).

The production of endogenous adenosine during secretagogue stimulation of CFTR leads to feedback inhibition limiting further chloride secretion in the rectal gland of the dogfish shark (Squalus acanthias). In the present study, we examined the role of AMP-kinase (AMPK) as an energy sensor also modulating chloride secretion through CFTR. We found that glands perfused with forskolin and isobutylmethylxanthine (F + I), potent stimulators of chloride secretion in this ancient model, caused significant phosphorylation of the catalytic subunit Thr172 of AMPK. These findings indicate that AMPK is activated during energy-requiring stimulated chloride secretion. In molecular studies, we confirmed that the activating Thr172 site is indeed present in the α-catalytic subunit of AMPK in this ancient gland, which reveals striking homology to AMPKα subunits sequenced in other vertebrates. When perfused rectal glands stimulated with F + I were subjected to severe hypoxic stress or perfused with pharmacologic inhibitors of metabolism (FCCP or oligomycin), phosphorylation of AMPK Thr172 was further increased and chloride secretion was dramatically diminished. The pharmacologic activation of AMPK with AICAR-inhibited chloride secretion, as measured by short-circuit current, when applied to the apical side of shark rectal gland monolayers in primary culture. These results indicate that that activated AMPK, similar to adenosine, transmits an inhibitory signal from metabolism, that limits chloride secretion in the shark rectal gland.

cGMP inhibition of type 3 phosphodiesterase is the major mechanism by which C-type natriuretic peptide activates CFTR in the shark rectal gland.

The in vitro perfused rectal gland of the dogfish shark (Squalus acanthias) and filter-grown monolayers of primary cultures of shark rectal gland (SRG) epithelial cells were used to analyze the signal transduction pathway by which C-type natriuretic peptide (CNP) stimulates chloride secretion. CNP binds to natriuretic receptors in the basolateral membrane, elevates cellular cGMP, and opens cystic fibrosis transmembrane conductance regulator (CFTR) chloride channels in the apical membrane. CNP-provoked chloride secretion was completely inhibitable by the nonspecific protein kinase inhibitor staurosporine and the PKA inhibitor H89 but insensitive to H8, an inhibitor of type I and II isoforms of cGMP-dependent protein kinase (cGKI and cGKII). CNP-induced secretion could not be mimicked by nonhydrolyzable cGMP analogs added alone or in combination with the protein kinase C activator phorbolester, arguing against a role for cGK or for cGMP-induced PKC signaling. We failed to detect a dogfish ortholog of cGKII by molecular cloning and affinity chromatography. However, inhibitors of the cGMP-inhibitable isoform of phosphodiesterase (PDE3) including milrinone, amrinone, and cilostamide but not inhibitors of other PDE isoenzymes mimicked the effect of CNP on chloride secretion in perfused glands and monolayers. CNP raised cGMP and cAMP levels in the SRG epithelial cells. This rise in cAMP as well as the CNP and amrinone-provoked chloride secretion, but not the rise in cGMP, was almost completely blocked by the Gαi-coupled adenylyl cyclase inhibitor somatostatin, arguing against a role for cGMP cross-activation of PKA in CNP action. These data provide molecular, functional, and pharmacological evidence for a CNP/cGMP/PDE3/cAMP/PKA signaling cascade coupled to CFTR in the SRG.

Gastric inhibitory peptide, serotonin, and glucagon are unexpected chloride secretagogues in the rectal gland of the skate (Leucoraja erinacea).

Since the discovery of the rectal gland of the dogfish shark 50 years ago, experiments with this tissue have greatly aided our understanding of secondary active chloride secretion and the secretagogues responsible for this function. In contrast, very little is known about the rectal gland of skates. In the present experiments, we performed the first studies in the perfused rectal gland of the little skate (Leucoraja erinacea), an organ weighing less than one-tenth of the shark rectal gland. Our results indicate that the skate gland can be studied by modified perfusion techniques and in primary culture monolayers, and that secretion is blocked by the inhibitors of membrane proteins required for secondary active chloride secretion. Our major finding is that three G protein-coupled receptor agonists, the incretin gastric inhibitory polypeptide (GIP), also known as glucose-dependent insulinotropic peptide, as well as glucagon and serotonin, are unexpected potent chloride secretagogues in the skate but not the shark. Glucagon stimulated chloride secretion to a mean value of 1,661 ± 587 µeq·h(-1)·g(-1) and serotonin stimulated to 2,893 ± 699 µeq·h(-1)·g(-1). GIP stimulated chloride secretion to 3,733 ± 679 µeq·h(-1)·g(-1) and significantly increased tissue cAMP content compared with basal conditions. This is the first report of GIP functioning as a chloride secretagogue in any species or tissue.

An endogenous peptide stimulates secretory activity in the elasmobranch rectal gland.

Extraction and partial purification of peptide material from the intestine of the elasmobranch Scyliorhinus canicula yielded a fraction that shows potent stimulatory activity in the rectal gland. The extracted material appears to contain an endogenous peptide (or peptides) that represents the natural hormone responsible for the control of rectal gland secretion in vivo.

Effect of colchicine on sensitivity of duck salt gland Na,K-ATPase to Na+.

Low molecular mass proteins of the FXYD family that affect the sensitivity of Na,K-ATPase to Na+ and K+ are known to be present in Na,K-ATPases in various tissues. In particular, in Na,K-ATPase from kidney a gamma-subunit (with electrophoretic mobility corresponding to molecular mass of about 10 kD) is present, and Na,K-ATPase preparations from heart contain phospholemman (electrophoretic mobility of this protein corresponds to molecular mass of 13-14 kD), which provides for the interaction of heart Na,K-ATPase with cytoskeletal microtubules. Disruption of microtubules by colchicine removes phospholemman from heart Na,K-ATPase preparations. The goal of the present study was to reveal a low molecular mass protein (probably a member of FXYD family) in preparation of Na,K-ATPase from duck salt glands. Immunoprecipitation of solubilized duck salt gland Na,K-ATPase using antibodies against alpha1-subunit results in the coprecipitation of a 13 kD protein with the Na,K-ATPase complex. Treatment of homogenate from duck salt glands with colchicine removes this protein from the purified preparation of Na,K-ATPase. Simultaneously, we observed a decrease in the sensitivity of Na,K-ATPase to Na+ at pH 6.5. However, colchicine treatment of homogenate from rabbit kidney does not affect either the sensitivity of Na,K-ATPase obtained from this homogenate to Na+ or the content of 10 kD protein (presumably gamma-subunit). The data suggest that phospholemman (or a similar member of the FXYD family) tightly interacts with Na,K-ATPase from duck salt glands and binds it to microtubules, simultaneously participating in the regulation of the sensitivity of Na,K-ATPase to Na+.

Vasoactive intestinal peptide, forskolin, and genistein increase apical CFTR trafficking in the rectal gland of the spiny dogfish, Squalus acanthias. Acute regulation of CFTR trafficking in an intact epithelium.

Defective trafficking of the cystic fibrosis transmembrane conductance regulator (CFTR) is the most common cause of cystic fibrosis. In chloride-secreting epithelia, it is well established that CFTR localizes to intracellular organelles and to apical membranes. However, it is controversial whether secretagogues regulate the trafficking of CFTR. To investigate whether acute hormonal stimulation of chloride secretion is coupled to the trafficking of CFTR, we used the intact shark rectal gland, a model tissue in which salt secretion is dynamically regulated and both chloride secretion and cellular CFTR immunofluorescence can be quantified in parallel. In rectal glands perfused under basal conditions without secretagogues, Cl- secretion was 151+/-65 microeq/h/g. Vasoactive intestinal peptide (VIP), forskolin, and genistein led to 10-, 6-, and 4-fold increases in Cl- secretion. In basal glands, quantitative confocal microscopy revealed CFTR immunofluorescence extending from the apical membrane deeply into the cell (7.28+/-0.35 micron). During stimulation with secretagogues, apical extension of CFTR immunofluorescence into the cell was reduced significantly to 3.24+/-0.08 micron by VIP, 4.08+/-0.13 by forskolin, and 3.19+/-0.1 by genistein (P < 0.001). Moreover, the peak intensity of CFTR fluorescence shifted towards the apical membrane (peak fluorescence 2.5+/-0.13 micron basal vs. 1.51+/-0.06, 1.77+/-0.1, and 1.38+/-0.05 for VIP, forskolin, and genistein; all P < 0.001). The increase in both Cl- secretion and apical CFTR trafficking reversed to basal values after removal of VIP. These data provide the first quantitative morphological evidence for acute hormonal regulation of CFTR trafficking in an intact epithelial tissue.

A1 adenosine receptors inhibit chloride transport in the shark rectal gland. Dissociation of inhibition and cyclic AMP.

In the in vitro perfused rectal gland of the dogfish shark (Squalus acanthias), the adenosine analogue 2-chloroadenosine (2Clado) completely and reversibly inhibited forskolin-stimulated chloride secretion with an IC50 of 5 nM. Other A1 receptor agonists including cyclohexyladenosine (CHA), N-ethylcarboxamideadenosine (NECA) and R-phenylisopropyl-adenosine (R-PIA) also completely inhibited forskolin stimulated chloride secretion. The "S" stereoisomer of PIA (S-PIA) was a less potent inhibitor of forskolin stimulated chloride secretion, consistent with the affinity profile of PIA stereoisomers for an A1 receptor. The adenosine receptor antagonists 8-phenyltheophylline and 8-cyclopentyltheophylline completely blocked the effect of 2Clado to inhibit forskolin-stimulated chloride secretion. When chloride secretion and tissue cyclic (c)AMP content were determined simultaneously in perfused glands, 2Clado completely inhibited secretion but only inhibited forskolin stimulated cAMP accumulation by 34-40%, indicating that the mechanism of inhibition of secretion by 2Clado is at least partially cAMP independent. Consistent with these results, A1 receptor agonists only modestly inhibited (9-15%) forskolin stimulated adenylate cyclase activity and 2Clado markedly inhibited chloride secretion stimulated by a permeant cAMP analogue, 8-chlorophenylthio cAMP (8CPT cAMP). These findings provide the first evidence for a high affinity A1 adenosine receptor that inhibits hormone stimulated ion transport in a model epithelia. A major portion of this inhibition occurs by a mechanism that is independent of the cAMP messenger system.

Inhibition by mercuric chloride of Na-K-2Cl cotransport activity in rectal gland plasma membrane vesicles isolated from Squalus acanthias.

The rectal gland of the dogfish shark is a model system for active transepithelial transport of chloride. It has been shown previously that mercuric chloride, one of the toxic environmental pollutants, inhibits chloride secretion in this organ. In order to investigate the mechanism of action of HgCl(2) at a membrane-molecular level, plasma membrane vesicles were isolated from the rectal gland and the effect of mercury on the activity of the Na-K-2Cl cotransporter was investigated in isotope flux studies. During a 30 s exposure HgCl(2) inhibited cotransport activity in a dose-dependent manner with an apparent K(i) of approx. 50 microM. The inhibition was complete after 15 s, partly reversible by dilution of the incubation medium and completely attenuated upon addition of reduced glutathione. The extent of inhibition by mercury depended on the ionic composition of the medium. The sensitivity of the cotransporter was highest when only the high affinity binding sites for sodium and chloride were saturated. Organic mercurials such as p-chloromercuribenzoic acid and p-chloromercuriphenylsulfonic acid at 100 microM did not inhibit the cotransporter, similarly exposure of the vesicles to 10 mM H(2)O(2) or 1 mM dithiothreitol for 30 min at 15 degrees C did not change cotransport activity. Transport activity was, however, reduced by 45.9+/-2.5% after an incubation with 3 mM N-ethylmaleimide for 20 min. Blocking free amino groups by N-hydroxysuccinimide or biotinamidocapronate-N-hydroxysulfosuccinimide had no effect. Investigations on the sidedness of the plasma membrane vesicles, employing the asymmetry of the (Na+K)-ATPase, demonstrated a right-side-out orientation in which the former extracellular face of the membrane is exposed to the incubation medium. In addition, extracellular mercury (5x10(-5) M) inhibited bumetanide-sensitive rubidium uptake into T84 cells by 48.5+/-7.1% after a 2 min incubation period. This inhibition was reversible in a manner similar to that observed in the plasma membrane vesicles. These studies suggest that in isolated rectal gland plasma membrane vesicles the Na-K-2Cl cotransporter (sNKCC1) exposes functionally relevant mercury binding sites at its external surface. These sites represent probably cysteines, the accessibility and/or sensitivity of which depends on the functional state of the transporter.

Induction of the catalytic protein of (Na+ plus K+)-ATPase in the salt gland of the duck.

The (Na+ plus K+)-ATPase activities in salt gland homogenates increased 3- to 4-fold after saline treatment of ducks for 3 weeks. The ATPase was purified to a specific activity of 460 and 1015 mumol Pi/mg protein per h, respectively, in control and saline-treated ducks. The catalytic protein was identified on polyacrylamide electrophoresis gels by phosphorylating the enzyme with (32P)ATP. The molecular weight of the protein was estimated to be 98 000. The amount of catalytic unit increased commensurately with the enzyme activity after saline treatment. It is therefore concluded that the increased enzyme activity is due to a de novo enzyme synthesis and is not an activation effect. Phospholipid concentration in the salt gland tissue increased 1.7-fold after the saline treatment. Significant increases occurred in the percentage of the total phospholipids as phosphatidylserine and sphingomyelin. In the partially purified (Na+ plus K+)-ATPase preparation, the percentage composition of phosphatidylserine and phosphatidylethanolamine increased after saline treatment.

K+-induced swelling of the dogfish shark (Squalus acanthias) rectal gland cells is associated with changes of the cytoskeleton.

Dogfish shark (Squalus acanthias) rectal gland cells swell massively when incubated in elasmobranch media in which Na+ was equivalently replaced by K+; this swelling was abolished when the impermeant gluconate replaced Cl-, while the cell depolarization was comparable in both media. The K+-effect was associated with (a) an increase of the steady-state 42K (and 86Rb) efflux (particularly of the rate constant of the fast cellular efflux component) and a rearrangement of the respective cellular pools of K+; (b) an alteration of cell morphology and the pattern of the F-actin staining along the basolateral cell membrane as revealed with fluorescent analogs of phallacidin. These changes were independent of cell volume, being identical in KCl and K-gluconate media. The observations were specific for K+ (and Rb+): replacement of media Na+ by Li+ (which is not actively extruded by the cells), or the presence of ouabain, produced only minor swelling without affecting cell morphology and F-acting distribution. The results are consistent with the following view: as opposed to Na+ or Li+ media, the K+-induced changes of the cortical F-actin component of the cytoskeleton permit the observed massive cell swelling due to the osmotic contribution of intracellular impermeant anion(s).

pCMBS-induced swelling of dogfish (Squalus acanthias) rectal gland cells: role of the Na+,K(+)-ATPase and the cytoskeleton.

(1) 0.1-1.0 mM p-chloromercuribenzene sulfonate (pCMBS) and some other organic mercurials produce a swelling of slices of dogfish shark (Squalus acanthias) rectal glands, with an uptake of cell Na+ and a loss of K+. In contrast, 1 mM N-ethylmaleimide (NEM) does not swell rectal gland cells (RGC), while affecting cell cations. (2) The slow entry of [203Hg]pCMBS is linearly related to its external concentration (10 microM-1 mM) and a small accumulation of pCMBS (apparent gradient about 3) in the cells occurs in 2 h. Cell 203Hg rapidly washes out of the cells (fast rate constant 0.153.min-1; slow rate constant 0.0067.min-1), and this efflux is accelerated by 1mM dithiothreitol. Thus, a major portion of pCMBS inter-acts rather loosely with cell components. (3) pCMBS and NEM share: (a) a negligible effect on the efflux of 86Rb+ and of [14C]urea; (b) a gradual inhibition of the cell Na+,K(+)-ATPase activity. (4) NEM as well as agents lowering cell glutathione accelerate and increase the pCMBS-induced cell swelling. Conditions inhibiting the Na+,K(+)-ATPase (ouabain, absence of Na+) have the same effect. (5) pCMBS, but not NEM produce a disappearance of the F-actin-phalloidin fluorescence independent of cell volume changes, particularly at the basolateral RGC membrane. (6) The data are consistent with the following set of events: (a) pCMBS (but not NEM) affects the cell membrane by increasing the efflux of the cell osmolyte taurine (Ziyadeh et al. (1988) Biochim. Biophys. Acta 943, 43-52 and unpublished data); (b) on entry into the cells, pCMBS and NEM interact with cell -SH, including those of the Na+,K(+)-ATPase; this action produces the observed changes in cell cations. Also, pCMBS, but not NEM, decrease F-actin at the membrane; (c) the inhibition of the Na+,K(+)-ATPase activity together with the decreased resistance of the cell membrane to stretch (absence of F-actin) produces the observed pCMBS-induced cell swelling by osmotic forces (intracellular non-diffusible anions).

The Na+, and Cl- content of goose salt gland slices and the effects of acetylcholine and ouabain.

In goose salt gland slices incubated in bicarbonate-buffered medium which contained 170 mEq of Na(+)/liter, net total tissue Na(+), expressed as milliequivalents per kilogram, was, in the presence of either acetylcholine (plus eserine) or ouabain, significantly higher than that of the bathing fluid. Acetylcholine caused an increase in the tissue Na(+) content as compared with untreated slices; there was an approximately equivalent decrease in K(+) and a significant decrease in Cl(-). The calculated net intracellular concentrations of Na(+), expressed as milliequivalents per liter of intracellular water, in unstimulated, acetylcholine-stimulated, and ouabain-treated slices were 2.1, 3.1, and 2.7 times higher, respectively, than the concentration of Na(+) in the bathing fluid. The net intracellular concentration of Na(+), expressed as milliequivalents per liter of intracellular water, in slices incubated in the presence of acetylcholine was 531 mEq/liter; this is approximately the same as the concentration of Na(+) in the secreted fluid of the goose salt gland (515 mEq/liter). The results indicate that the main concentration gradient for Na(+) could be established across the basal membrane. The data do not indicate whether this involves active transport of Na(+) per se. A second stage which might involve Na-K ATPase activity at the luminal membrane is discussed. The sum of the total tissue Na(+) and K(+) was approximately 250 mEq/kg, whereas the Cl(-) content was only approximately 130 mEq/kg.

The formation and continuous turnover of a fraction of phosphatidic acid on stimulation of NaC1 secretion by acetylcholine in the salt gland.

Acetylcholine, which stimulates NaCl secretion in the avian salt gland, causes the rapid formation of a fraction of phosphatidic acid, as measured by (32)P incorporation, which amounts maximally to about 0.18 micromoles per g of fresh tissue. This does not appear to involve synthesis of the diglyceride moiety of phosphatidic acid, as measured by glycerol-1-(14)C incorporation. It presumably involves formation of phosphatidic acid by the diglyceride kinase pathway from preformed diglyceride and ATP. The specific activity of the AT(32)P of the tissue is not increased in the presence of acetylcholine. At time intervals after addition of acetylcholine during which a full response, measured as increased O(2) uptake, may be observed, phosphatidic acid appears to be the only phosphatide which shows any increase either in total (32)P radioactivity or in net specific acitvity. This responsive fraction of phosphatidic acid undergoes continuous turnover of its phosphate moiety. There is no evidence that this turnover is due to the phosphatidic acid acting as a pool of intermediate for the synthesis of other phospholipids or glycerides. The responsive fraction amounts to not more than 20% of the total phosphatidic acid of the tissue; it does not mix with the other (non-responsive) phosphatidic acid of the tissue. The observations suggest that this phosphatidic acid plays some role in the over-all secretory process.

Two K+ channel types, muscarinic agonist-activated and inwardly rectifying, in a Cl- secretory epithelium: the avian salt gland.

Patches of membrane on cells isolated from the nasal salt gland of the domestic duck typically contained two types of K+ channel. One was a large-conductance ("maxi") K+ channel which was activated by intracellular calcium and/or depolarizing membrane voltages, and the other was a smaller-conductance K+ channel which exhibited at least two conductance levels and displayed pronounced inward rectification. Barium blocked both channels, but tetraethylammonium chloride and quinidine selectively blocked the larger K+ channel. The large K+ channel did not appear to open under resting conditions but could be activated by application of the muscarinic agonist, carbachol. The smaller channels were open under resting conditions but the gating was not affected by carbachol. Both of these channels reside in the basolateral membranes of the Cl- secretory cells but they appear to play different roles in the life of the cell.

Modulation of inositol(1,4,5)trisphosphate-sensitive calcium store content during continuous receptor activation and its effects on calcium entry.

Changes in intracellular Ca2+ concentration ([Ca2+]i) following the activation of muscarinic receptors with carbachol were studied in cells from the exocrine avian nasal gland that had been maintained in culture for 40-48 h. In these cells, the carbachol-induced sustained increase in [Ca2+]i could be further increased by the subsequent addition of thapsigargin. This increase was due to an additional release of intracellular Ca2+ and a corresponding further enhancement of Ca2+ entry. However, thapsigargin-sensitive and Ins(1,4,5)P3-sensitive stores appeared to be coincident and the initial carbachol stimulus was sufficient to completely empty these stores. It was concluded that the subsequent effect of thapsigargin was due to a partial refilling of the Ins(1,4,5)P3-sensitive stores despite the continued presence of agonist, an effect that was not the result of any decline in levels of cellular Ins(1,4,5)P3 or changes in the generation of Ins(1,3,4,5)P4, which were sustained throughout. Possible explanations for this refilling response include compartmentalization of intracellular Ins(1,4,5)P3, or a desensitization of the Ins(1,4,5)P3 receptor/Ca(2+)-release channel. Alternatively, the data are also compatible with a recently proposed kinetic separation of Ca2+ uptake and release sites. An important implication of this particular interpretation of our findings would be an apparent dependence of Ca2+ entry specifically on the status of the Ca(2+)-uptake component of the agonist-sensitive store, rather than the Ca(2+)-release component.

Atrial natriuretic factor controls salt gland secretion in the Pekin duck (Anas platyrhynchos) through interaction with high affinity receptors.

Marine birds possess supraorbital salt-secreting glands in addition to the kidneys as osmoregulatory organs to excrete a strongly hypertonic salt solution of mainly NaCl. Atrial natriuretic factor (ANF)-like peptides could be demonstrated immunocytochemically in duck atria, but not in the salt glands. To elucidate the putative role of bird-specific ANF (cANF) in the control of salt gland function, conscious saltwater-acclimated Pekin ducks received 15 pmol/min.kg BW cANF for 10 min at two states of salt gland activity. During steady state diuresis and salt gland secretion induced by systemic infusion of 1.0 ml/min isotonic Krebs-Ringer solution, cANF applied iv enhanced the secretion rate from 0.20 to 0.29 ml/min and the osmolality of secretion from 870 to 920 mosmol/kg. At threshold conditions of salt gland activity, cANF infused intracarotideally stimulated the secretion rate from 0.07 to 0.15 ml/min at elevated osmolality of 760 compared to 480 mosmol/kg. Mean arterial pressure and heart rate remained unchanged. Receptor autoradiography with [125I]Bolton-Hunter-cANF as ligand demonstrated specific binding sites throughout the salt gland tissue of both freshwater and saltwater ducks. Scatchard analysis using an enriched membrane fraction revealed high affinity (Kd = 0.9 nM) binding sites of 270 fmol/mg protein density. Displacement studies with unlabeled cANF and human ANF showed comparable Ki values for both peptides in freshwater and saltwater ducks. The combined results indicate an important role for cANF in the control of avian salt gland function.

Angiotensin and converting enzyme regulate extrarenal salt excretion in ducks.

Numerous previous studies have proposed a salt-conserving role for the renin-angiotensin system in mammals, but there is little evidence of this putative role in birds. Especially interesting are marine birds, which have a relatively limited ability to regulate the osmolality and ionic composition of their urine but possess extrarenal salt glands capable of excreting a highly concentrated NaCl solution. In the present experiments, hypertonic saline, angiotensin I (ANG I), and captopril were infused iv into chronically cannulated ducks to study the neuroendocrine, cardiovascular, renal, and extrarenal excretory responses to osmotic stress. Infusion of hypertonic saline elicited nasal salt excretion, which could be stopped completely by coadministration of ANG I. The effective dose of ANG I increased the plasma norepinephrine (NE) concentration, but did not alter heart rate or arterial blood pressure. Captopril enhanced extrarenal salt excretion in the saline-loaded ducks. The converting enzyme inhibitor also blocked the noradrenergic and NaCl-retaining actions of ANG I; conversely, coadministration of captopril and ANG I increased the plasma epinephrine (E) concentration. These findings indicate that the renin-angiotensin system, in addition to effects on the sympathoadrenal system, regulates NaCl and water metabolism in birds with extrarenal salt glands.

Regulation of the Na+2Cl­K+ cotransporter in in vitro perfused rectal gland tubules of Squalus acanthias.

Previously it has been shown that the Na+2Cl­K+ cotransporter accepts NH4 + at its K+ binding site. This property can be used to estimate its transport rates by adding NH4 + to the bath and measuring the initial furosemide-dependent rates of change in BCECF fluorescence. We have utilized this technique to determine the regulation of the furosemide-inhibitable Na+2Cl­K+ cotransporter in in vitroperfused rectal gland tubules (RGT) of Squalus acanthias. Addition of NH4 + to the bath (20 mmol/l) led to an initial alkalinization, corresponding to NH3 uptake. This was followed by an acidification, corresponding to NH4 + uptake. The rate of this uptake was quantified by exponential curve fitting and is given in arbitrary units (Δfluorescence/time). This acidification could be completely inhibited by furosemide. In the absence of any secretagogue preincubation of RGT in a low Cl­ solution (6 mmol/l, low Cl­) for 10 min enhanced the uptake rate significantly from 4.04±0.51 to 12.7±1.30 (n=5). The addition of urea (200 mmol/l) was without effect, but the addition of 300 mmol/l mannitol (+300 mannitol) enhanced the rate significantly from 7.24±1.33 to 14.7±4.6 (n=6). Stimulation of NaCl secretion by a solution maximizing the cytosolic cAMP concentration (Stim) led to a significant increase in NH4 + uptake rate from 5.00±1.33 to 13.3±1.54 (n=6). Similar results were obtained in the additional presence of Ba2+ (1 mmol/l): the uptake rate was increased significantly from 4.23±0.34 to 15.1±1.86 (n=16). In the presence of Stim low Cl­ had no additional effect on the uptake rate: 15.1±3.1 versus 15.2±2.8 in high Cl­ (n=6). The uptake rate in Stim containing additional +300 mannitol (22.3±4.0, n=5) was not significantly different from that obtained with Stim or +300 mannitol alone. By whatever mechanism the NH4 + uptake rate was increased furosemide (500 µmol/l) always reduced this rate to control values. Hence three manoeuvres enhanced furosemide-inhibitable uptake rates of the Na+2Cl­K+ cotransporter probably independently: (1) lowering of cytosolic Cl­ concentration; (2) cell shrinkage; and (3) activation by cAMP.

Does stimulation of NaCl secretion in in vitro perfused rectal gland tubules of Squalus acanthias increase membrane capacitance?

NaCl secretion in rectal gland tubules (RGT) of Squalus acanthias requires the activation of Cl­ channels in the luminal membrane. The RGT and its mechanism of activation are an early evolutionary paradigm of exocrine secretion. The respective Cl­ channels probably resemble the shark equivalent of the cystic fibrosis transmembrane conductance regulator (CFTR). Activation of these Cl­ channels occurs via cAMP. It has been hypothesized that the activation of CFTR occurs via exocytosis or inhibited endocytosis. To examine this question directly by electrical measurements we have performed whole-cell patch-clamp analyses of in vitro perfused RGT. NaCl secretion was stimulated by a solution (Stim) containing forskolin (10 µmol/l), dibutyryl-cAMP (0.5 mmol/l) and adenosine (0.5 mmol/l). This led to the expected strong depolarization and an increase in membrane conductance (G m). The membrane capacitance (C m) was measured by a newly devised two-frequency synchronous detector method. It was increased by Stim significantly from 5.00±0.22 to 5.17±0.21 pF (n=50). The increase in C m correlated with the increase in G m with a slope of 51 fF/nS. Next the effect of furosemide (500 µmol/l) was examined in previously stimulated RGT. Furosemide was supposed to inhibit coupled Na+2Cl­K+ uptake and to reduce cell volume but not membrane trafficking of Cl­ channels. Furosemide reduced G m slightly (due to the fall in cytosolic Cl­ concentration) and C m to the same extent by which Stim had increased it. Both changes were statistically significant, and the slope of ΔC m/ΔG m was similar to that caused by Stim. Inhibitors of microtubules or actin (colchicine, phalloidin and cytochalasin D added at 10 µmol/l to the pipette solution and dialysed for >10 min) did not alter cell voltage, G m or C m, nor did these inhibitors abolish the stimulatory effect of cAMP. These data suggest that the small C m changes observed with Stim reflect a minor cell volume increase and an "unfolding" of the plasma membrane. The present data do not support the exocytosis/endocytosis hypothesis of cAMP-mediated activation of Cl­ channels in these cells.