HCO3- absorption in rabbit outer medullary collecting duct: role of luminal carbonic anhydrase

Membrane-bound luminal carbonic anhydrase (CA) IV, by catalyzing the dehydration of carbonic acid into CO2 plus water, facilitates H+ secretion in the renal outer medullary collecting duct from the inner stripe (OMCDi). To examine the role of CA IV on H+ secretion, we measured net HCO3- transport in perfused OMCDi segments and examined the effect on transport of two extracellular CA inhibitors, benzolamide and F-3500, aminobenzolamide coupled to a nontoxic polymer, polyoxyethylene bis(acetic acid) [synthesized and kindly provided by C. Conroy and T. Maren (C. W. Conroy, G. C. Wynns, and T. H. Maren. Bioorg, Chem, 24: 262-272, 1996)]. These agents would inhibit only the luminal CA enzyme. Dose titration curves for net HCO3- flux were performed for each drug. Basal HCO3- absorptive flux was 12 pmol.min-1.mm-1 in control segments and significantly increased to 16 pmol.min-1.mm-1 in segments from 3-day acid-treated animals. The concentrations of benzolamide and F-3500 that inhibited HCO3- absorption by 50% were approximately 0.1 and approximately 5 microM, similar to the Ki for CA IV inhibition by these agents (0.2 and 4.0 microM, respectively; T. Maren, C. W. Conroy, G. C. Wynns, and D. R. Godman. J. Pharmacol. Exp. Ther. 280: 98-105, 1997). Adding exogenous CA to the inhibitor in the perfusate nearly restored basal HCO3- transport, suggesting that cytosolic CA II was not inhibited by these impermeant inhibitors. In OMCDi segments from acidotic rabbits, the concentrations of benzolamide and F-3500 that inhibited HCO3- absorption by 50% were 50 and 500 microM, respectively, > 100 times the Ki for CA IV inhibition and for inhibition of HCO3- transport in control tubules. Thus, in the OMCDi, doses of extracellular CA inhibitors that inhibited approximately 50% of CA IV activity also comparably inhibited HCO3- transport, indicating that H+ secretion depends in part on the availability of luminal CA IV activity. Acidosis substantially decreased the sensitivity of HCO3- transport to CA inhibition.

Gastric branch vagotomy and gastric emptying during and after intragastric infusion of glucose

The effect of gastric branch vagotomy (GVX) on the gastric emptying of glucose was evaluated during two phases of emptying control: as the stomach fills and in the postload period. GVX and control rats received a series of intragastric glucose infusions (1.0 ml/min) through indwelling gastric fistulas. In experiment 1, gastric samples were withdrawn either immediately after the offset of 9- or 18-min infusions of 12.5% glucose or at various times up to 36 min postinfusion. In experiment 2, samples were withdrawn either immediately or 30 min after termination of 12-min infusions of 12.5 or 25% glucose. After gastric fill, glucose solute emptying rate was stable over time not influenced by concentration doubling, and, surprisingly, not affected by GVX. During gastric fill, solute emptying rate doubled with concentration in both GVX and control rats. For each concentration, however, glucose emptied during fill at almost twice the rate in GVX compared with control rats. This accelerated emptying of glucose during fill in GVX rats is consistent with a gastric vagal contribution to inhibitory mechanisms (e.g., receptive relaxation) that operate as the stomach fills under normal conditions. The absence of a GVX effect on emptying after fill suggests either that gastric branch vagal efferents play little role in feedback inhibitory control of glucose emptying under normal conditions or that other systems compensate for the function previously served by vagal gastric branch efferents. Further work is required to address the possible role of the gastric vagus in feedback control of gastric emptying when nutritive fluids other than glucose are delivered.

Hyperammonaemia with distal renal tubular acidosis

The case is reported of an infant with hyperammonaemia secondary to severe distal renal tubular acidosis. A clinical association between increased concentrations of ammonia in serum and renal tubular acidosis has not previously been described. In response to acidosis the infant's kidneys presumably increased ammonia synthesis but did not excrete ammonia, resulting in hyperammonaemia. The patient showed poor feeding, frequent vomiting, and failure to thrive, but did not have an inborn error of metabolism. This case report should alert doctors to consider renal tubular acidosis in the differential diagnosis of severely ill infants with metabolic acidosis and hyperammonaemia.

Subdiaphragmatic vagal deafferentation fails to block feeding-suppressive effects of LPS and IL-1 beta in rats

To evaluate the role of subdiaphragmatic vagal afferent fibers in mediating the inhibition of food intake produced by peripheral administration of bacterial lipopolysaccharide (LPS) and the proinflammatory cytokine interleukin-1 beta (IL-1 beta), we assessed the ability of 100 micrograms/kg ip LPS and 2 micrograms/kg ip human recombinant IL-1 beta to suppress solid food intake during the first 3 and 6 h of the dark cycle in rats with selective vagal rootlet deafferentation (SDA, n = 15) and in sham surgical control rats (Con, n = 17). SDA was produced by a combination of dorsal subdiaphragmatic truncal vagotomy and left vagal afferent rootlet transection as the left vagus enters the caudal brain stem. Both LPS and IL-1 beta significantly suppressed food intake at 3 and 6 h in both Con and SDA rats, and SDA failed to attenuate the LPS- and IL-1 beta-induced reductions in food consumption relative to the suppression seen in controls. Peripheral administration of the gut-brain peptide cholecystokinin (CCK) suppressed 30-min 12.5% liquid glucose consumption in control, but not in SDA rats, consistent with previous demonstrations of the role of subdiaphragmatic vagal afferents in the mediation of CCK satiety. These data demonstrate that subdiaphragmatic vagal afferents are not necessary for the feeding-suppressive actions of peripherally administered LPS and IL-1 beta and suggest that peripheral LPS and IL-1 beta may inhibit food intake via humoral and/or splanchnic visceral afferent pathways.

Relationships between gastric motility and gastric vagal afferent responses to CCK and GRP in rats differ

The brain-gut peptides cholecystokinin (CCK) and the mammalian bombesin-like peptide gastrin-releasing peptide (GRP) suppress food intake. Vagotomy blocks CCK- but not bombesin (BN)-induced feeding suppression, demonstrating differential vagal contributions. We examined the relationship between the ability of CCK and the active fragment of GRP, GRP-(18-27), to stimulate gastric vagal afferent activity and their ability to elicit changes in gastric motility. We also examined ligated cervical vagal segments and revealed specific 125I-CCK vagal binding without evidence of radiolabeled BN binding sites. Both close arterial and intraperitoneal CCK and GRP-(18-27) produced dose-dependent increases in activity in gastric vagal mechanoreceptive afferents. CCK dose dependently decreased gastric pressure without altering antral wall tension, whereas GRP-(18-27) dose dependently increased both gastric pressure and peak antral wall muscle tension. These results suggest that GRP-(18-27) activates gastric vagal afferents secondary to its stimulation of gastric motor effects. CCK activates this same population of vagal afferents independent of changes in gastric tension, suggesting a direct action of CCK at functional vagal CCK receptors.

Defective renal calcium reabsorption in genetic hypercalciuric rats

Idiopathic hypercalciuria is a frequent cause of calcium (Ca) containing kidney stones. We have previously shown that there is increased intestinal Ca absorption in selectively inbred genetic hypercalciuric stone forming (GHS) rats; however, excess Ca excretion persists when the rats are fed a low Ca diet indicating a defect in renal Ca reabsorption and/or increased bone resorption. To determine if GHS rats have a defect in renal Ca reabsorption we performed 14C-inulin clearance studies on parathyroidectomized female GHS and control (Ctl) rats. After three baseline collections, chlorothiazide (CTZ) or furosemide (FUR) was infused and three more collections were obtained. Both GFR and filtered load of Ca did not differ among the groups; however, fractional and absolute excretion (UcaV) of Ca was three times higher in GHS rats. The increased Ca excretion was not diminished by a low Ca diet. Urine flow rate nearly tripled in all rats after either FUR or CTZ. After CTZ, UcaV was decreased to a greater extent in GHS compared to Ctl rats. After FUR, UcaV was increased to a greater extent in Ctl rats compared to GHS rats. These data indicate that GHS rats have a defect in renal Ca reabsorption, in addition to increased intestinal Ca absorption. The effect of CTZ was greater, and that of FUR was smaller, in GHS compared with Ctl rats, suggesting that the defect in renal Ca handling might be at the level of the thick ascending limb.

Expression of carbonic anhydrase IV mRNA in rabbit kidney: stimulation by metabolic acidosis

The renal carbonic anhydrases, CA II (cytosolic) and CA IV (membrane bound), are believed to facilitate renal acid secretion. We have recently shown that renal cortical sodium dodecyl sulfate (SDS)-resistant hydratase (presumably CA IV) activity was stimulated 241% during chronic metabolic acidosis (CMA). In the present study, we examined the expression and regulation of CA IV mRNA in kidneys from control and acidotic rabbits. To obtain a CA IV probe, we reverse transcribed rabbit kidney total RNA and amplified a approximately 780-base pair (bp) DNA product using primers derived from the human CA IV sequence. Using this product, we screened one-half of a kidney cortex cDNA library and sequenced a 1,194-bp cDNA, which contained the entire open-reading frame of rabbit CA IV. The cDNA was 78% identical to human and 71% to rat CA IV. The deduced amino acid sequence projected an active zinc binding site and two glycosylation sites. Northern analysis yielded a single transcript of approximately 1,600 bp in size expressed more abundantly in cortex and inner medulla than in outer medulla. CA IV mRNA was also expressed abundantly in lung but not in liver or spleen. The high abundance of CA IV mRNA in inner medulla was localized by in situ hybridization to medullary collecting duct cells. Rabbits exposed to CMA showed significant upregulation of CA IV mRNA expression in kidney cortex and outer medulla. Despite a numerical increase, excessive variability precluded statistical significance in the inner medulla. Thus CA IV mRNA was expressed abundantly in kidney and stimulated by CMA, similar to what has been previously observed for SDS-resistant hydratase (presumed CA IV) activity. It is likely that the regulation of CA IV mRNA and activity is relevant to the kidney's adaptation to CMA.

Vagal afferent and efferent contributions to the inhibition of food intake by cholecystokinin

To assess the role of subdiaphragmatic vagal afferent and efferent fibers in the mediation of the inhibition of food intake by cholecystokinin (CCK), we compared the ability of a dose range (1-16 microg/kg), of CCK to affect 30-min liquid glucose (0.125 g/ml) intake in rats with either total subdiaphragmatic vagotomy, selective subdiaphragmatic vagal deafferentation, selective subdiaphragmatic vagal deefferentation, or sham surgery. Selective vagal deafferentation and deefferentations were produced by combinations of unilateral subdiaphragmatic vagotomy and contralateral afferent or efferent rootlet transection as fibers enter the caudal medulla. CCK produced a dose-related suppression of glucose intake in sham animals, and this action was eliminated in rats with total subdiaphragmatic vagotomy. CCK suppression of intake was attenuated in rats with vagal deafferentation, such that there was a loss of sensitivity to CCK. Vagal deefferentation resulted in lower levels of baseline intake and a truncation of the feeding-inhibitory actions of CCK. These data demonstrate that CCK's suppression of intake depends on actions of both vagal afferent and efferent fibers. We interpret these data as suggesting that 1) the actions of low doses of CCK depend on activation of vagal afferent CCK receptors and 2) the greater efficacy of higher CCK doses is the result of the potentiation of these vagal afferent actions due to local physiological gastrointestinal effects of the peptide that rely on vagal efferent input.

Metabolic acidosis stimulates H+ secretion in the rabbit outer medullary collecting duct (inner stripe) of the kidney

The outer medullary collecting duct (OMCD) absorbs HCO3- at high rates, but it is not clear if it responds to metabolic acidosis to increase H+ secretion. We measured net HCO3- transport in isolated perfused OMCDs taken from deep in the inner stripes of kidneys from control and acidotic (NH4Cl-fed for 3 d) rabbits. We used specific inhibitors to characterize the mechanisms of HCO3- transport: 10 microM Sch 28080 or luminal K+ removal to inhibit P-type H+,K+-ATPase activity, and 5-10 nM bafilomycin A1 or 1-10 nM concanamycin A to inhibit H+-ATPase activity. The results were comparable using either of each pair of inhibitors, and allowed us to show in control rabbits that 65% of net HCO3- absorption depended on H+-ATPase (H flux), and 35% depended on H+,K+-ATPase (H,K flux). Tubules from acidotic rabbits showed higher rates of HCO3- absorption (16.8+/-0.3 vs. 12.8+/-0.2 pmol/min per mm, P < 0.01). There was no difference in the H,K flux (5.9+/-0.2 vs. 5.8+/-0.2 pmol/min per mm), whereas there was a 61% higher H flux in segments from acidotic rabbits (11.3+/-0.2 vs. 7.0+/-0.2 pmol/min per mm, P < 0.01). Transport was then measured in other OMCDs before and after incubation for 1 h at pH 6.8, followed by 2 h at pH 7.4 (in vitro metabolic acidosis). Acid incubation in vitro stimulated HCO3- absorption (12.3+/-0.3 to 16.2+/-0.3 pmol/min per mm, P < 0.01), while incubation at pH 7.4 for 3 h did not change basal rate (11.8+/-0.4 to 11.7+/-0.4 pmol/min per mm). After acid incubation the H,K flux did not change, (4.7+/-0.4 to 4.6+/-0.4 pmol/min per mm), however, there was a 60% increase in H flux (6.6+/-0.3 to 10.8+/-0.3 pmol/min per mm, P < 0.01). In OMCDs from acidotic animals, and in OMCDs incubated in acid in vitro, there was a higher basal rate and a further increase in HCO3- absorption (16.7+/-0.4 to 21.3+/-0.3 pmol/min per mm, P < 0.01) because of increased H flux (11.5+/-0.3 to 15.7+/-0.2 pmol/min per mm, P < 0.01) without any change in H,K flux (5.4+/-0.3 to 5.6+/-0.3 pmol/min per mm). These data indicate that HCO3- absorption (H+ secretion) in OMCD is stimulated by metabolic acidosis in vivo and in vitro by an increase in H+-ATPase-sensitive HCO3- absorption. The mechanism of adaptation may involve increased synthesis and exocytosis to the apical membrane of proton pumps. This adaptation helps maintain homeostasis during metabolic acidosis.

Endogenous CCK in the control of gastric emptying of glucose and maltose

A role for endogenous cholecystokinin (CCK) in the control of gastric emptying of liquid glucose and maltose test meals in rhesus monkeys was assessed. Intragastric administration of a dose range (10-100 micrograms/kg) of the CCKA receptor antagonist devazepide produced a dose dependent acceleration of the emptying of 100 ml 300 mOsm test meals of glucose and maltose but had no effect on the emptying of a hyperosmotic (750 mOsm) NaCl solution. At the 100 micrograms/kg dose, the emptying of glucose and maltose meals were as rapid as the emptying of physiological NaCl. These data expand the demonstrated role of endogenous CCK in the slowing of gastric emptying of nutrients in rhesus monkeys to carbohydrates and suggest that previous negative results were due to the hyperosmotic nature of the glucose solutions.

Bombesin and cholecystokinin differentially affect ingestive microstructural variables whether given alone or in combination

The ability of dose combinations of cholecystokinin (CCK) and bombesin to inhibit liquid glucose (0.125 gm/ml) intake and affect microstructural components of ingestive behavior in rats was examined. Five minutes before access to the glucose solution, rats were injected with dose pairs of CCK and bombesin. Both CCK and bombesin inhibited intake in a dose-related fashion. The magnitude of the inhibition produced by dose combinations was never greater than the sum of the inhibitions produced by the individual doses. CCK and bombesin affected different microstructural components of ingestion. CCK reduced burst size and cluster size, whereas bombesin reduced burst number and cluster number. These effects of the 2 peptides were not altered by the presence of the other peptide. These results suggest that different mechanisms of action underlie the feeding inhibitory actions of the 2 peptides.

Adaptation of rabbit cortical collecting duct HCO3- transport to metabolic acidosis in vitro

Net HCO3- transport in the rabbit kidney cortical collecting duct (CCD) is mediated by simultaneous H+ secretion and HCO3- secretion, most likely occurring in a alpha- and beta-intercalated cells (ICs), respectively. The polarity of net HCO3- transport is shifted from secretion to absorption after metabolic acidosis or acid incubation of the CCD. We investigated this adaptation by measuring net HCO3- flux before and after incubating CCDs 1 h at pH 6.8 followed by 2 h at pH 7.4. Acid incubation always reversed HCO3- flux from net secretion to absorption, whereas incubation for 3 h at pH 7.4 did not. Inhibition of alpha-IC function (bath CL- removal or DIDS, luminal bafilomycin) stimulated net HCO3- secretion by approximately 2 pmol/min per mm before acid incubation, whereas after incubation these agents inhibited net HCO3- absorption by approximately 5 pmol/min per mm. Inhibition of beta-IC function (luminal Cl- removal) inhibited HCO3- secretion by approximately 9 pmol/min per mm before incubation, whereas after incubation HCO3- absorption by only 3 pmol/min per mm. After acid incubation, luminal SCH28080 inhibited HCO3- absorption by only 5-15% vs the circa 90% inhibitory effect of bafilomycin. In outer CCDs, which contain fewer alpha-ICs than midcortical segments, the reversal in polarity of HCO3- flux was blunted after acid incubation. We conclude that the CCD adapts to low pH in vitro by downregulation HCO3- secretion in beta-ICs via decreased apical CL-/base exchang activity and upregulating HCO3- absorption in alpha-ICs via increased apical H+ -ATPase and basolateral CL-/base exchange activities. Whether or not there is a reversal of IC polarity or recruitment of gamma-ICs in this adaptation remains to be established.

Postnatal differentiation of rabbit collecting duct intercalated cells

The newborn has a limited ability to regulate H+/HCO3- homeostasis, due in part to immaturity of the intercalated cells in the distal nephron. We traced the postnatal differentiation of the intercalated cells of the rabbit cortical collecting duct (CCD) and outer medullary collecting duct (OMCD) using MAb to the 31-kD subunit of the vacuolar H(+)-ATPase, membrane portion of erythrocyte band 3, and apical surface of B-intercalated cells (peanut agglutinin [PNA], MAb B63). In the most superficial CCD of the newborn there was no binding to these probes, although deeper in the cortex there was faint apical staining with PNA and MAb B63 and a few patterns of H(+)-ATPase and band 3 labeling of neonatal intercalated cells. The OMCD showed mostly apical H(+)-ATPase and both cytoplasmic and basolateral band 3 labeling but B-intercalated cell markers were not seen. By 3 wk of age the staining of the CCD and OMCD was more polarized, resembling those in the adult. Band 3 positive cells (as a percentage of total cells) in the CCD increased from 13 to 17% during maturation, and in the OMCD they increased from 22 to 37%. Some basolateral band 3 and apical H(+)-ATPase staining was also seen in the inner medullary collecting duct of 3-wk-old rabbits to a greater extent than in newborn or adult rabbits. Labeling of intercalated cells in the CCD and OMCD was weakest and least numerous in the newborn, greater in the 3 wk old, and greatest in the adult. Most maturing cortical intercalated cells bound both PNA and H(+)-ATPase MAb, comparable to what has been observed in the adult CCD. PNA-negative cells showing apical H(+)-ATPase labeling, consistent with the classic A-intercalated cell phenotype, comprised only 5% of identified intercalated cells in the newborn CCD compared with 12% in older animals. In or near the developing renal vesicles and ampullary structures were occasional cytoplasmically staining PNA- and B63-positive cells. Whether these cells are precursors of specific renal tubular cells cannot yet be established. Staining for principal cells (ST.9) was less intense in the neonatal cortex than in more mature cortex, but the deep cortex and outer medulla were heavily labeled at all ages. These data indicate that immature intercalated cells, in the CCD and OMCD, may undergo significant postnatal proliferation and differentiation, acquiring mature phenotypes during the first month of life. The A-intercalated cell appears more differentiated than the B cell during the 1st wk of life, suggesting that A-intercalated cells contribute more than B cells to the maintenance of acid-base homeostasis in the newborn.

Sub-diaphragmatic vagal afferent integration of meal-related gastrointestinal signals

We have established a method to investigate the range of mechanical, nutrient chemical and peptidergic meal-related stimuli t hat may generate vagal afferent neurophysiological signals critical to the negative feedback control of food intake in the rat. We have identified populations of fibers that respond with increased neurophysiological discharge rates to gastric loads, duodenal loads, and close celiac arterial administration of a brain-gut peptide, cholecystokinin. Load-sensitive fibers with gastric and duodenal mechanoreceptive fields are able to integrate information arising from mechanical and peptidergic stimulation, where cholecystokinin octapeptide (CCK) administration potentiates subsequent responses to distending loads, and synergizes with distending loads to produce greater excitation than either load stimulus alone or peptide stimulation alone. In addition, we have identified situations where the duodenal presence of nutrients modifies the vagal afferent activity of gastric load-sensitive fibers. Thus, our approach can mimic the temporal and spatial distribution of meal-related stimuli in the gut, and reveals the potential for nutrients in one gastrointestinal compartment to affect neutral signals arising from another gut compartment.

Developmental injury to the cerebellum following perinatal Borna disease virus infection

In rats infected as neonates, Borna disease virus (BDV) infection causes neuroanatomical, behavioral and physiological abnormalities without encephalitis. Neonatal infection with BDV provides a powerful model for studying the effects of virus replication on brain development without inflammation-induced brain damage. Here we report that neonatal BDV infection interfered with cerebellar development in the Lewis rat. Based on cerebellar cross-sectional area measurements, abnormal cerebellar growth was first noted between 7 and 14 days after infection. Reactive astrocytosis was evident by three days after infection, even without encephalitis, and even before identification of viral proteins in the cerebellum. While neonatal BDV infection caused a significant loss in granule cells, infected granule cells were not identified. BDV proteins were readily detected in the Purkinje cells. Thus, persistent BDV infection of Purkinje cells, but not granule cells, was associated with loss of granule cells during cerebellar development, in the absence of encephalitis.

Integration of vagal afferent responses to duodenal loads and exogenous CCK in rats

The neurophysiological responses to 0.1 ml duodenal balloon inflation, 0.5 ml duodenal loads of normal saline, and 100 pmol close celiac arterial infusions of cholecystokinin (CCK) were obtained from 14 left cervical vagal afferent fibers in 14 rats. Duodenal, but not gastric, loads increased discharge rates in these slowly adapting fibers. CCK alone excited these fibers, and CCK pretreatment amplified subsequent duodenal load responses. Furthermore, duodenal loads generated greater responses when combined with CCK infusions. The small (< 3 mm) receptive fields of these fibers were localized to the ventral wall of the proximal duodenum, with C fiber conduction velocities (< 2 m/s). These results demonstrate for the first time rat duodenal load-sensitive vagal afferents. They can integrate signals arising from CCK and duodenal loads, and may mediate aspects of the role of CCK in the inhibition of gastric emptying and the control of food intake.

Expression of acid-base-related proteins in mesonephric kidney of the rabbit

The mesonephric kidney, precursor to the metanephric kidney, comprises 30-50 nephrons, each with a glomerulus and proximal, distal, and collecting tubules. Although two different cell types have been identified in the mesonephric collecting tubule, no relationship to cells of the metanephric collecting duct has been established. To characterize expression of some of the acid-base-related proteins, we assayed for carbonic anhydrase (CA) activity and performed immunocytochemistry in mesonephroi from 15- to 20-day-old fetal rabbits. From total RNA, we detected expression of CA II and CA IV mRNA. Microdissected proximal and collecting tubules abundantly expressed both CA II and CA IV, at least to the extent observed in mature metanephric proximal tubules and collecting ducts. Histochemistry confirmed the expression of CA activity in these segments; in the collecting tubule, 28% of the collecting tubule cells were CA rich. Most CA-rich cells showed apical H(+)-ATPase and basolateral band 3 anion exchanger staining consistent with the findings in mature H(+)-secreting (alpha) intercalated cells of the metanephric collecting duct. CA-negative cells could be labeled with an antibody that identifies mature metanephric principal cells. Thus the mesonephric collecting tubule has many cells resembling mature alpha-intercalated cells and a majority of cells resembling principal cells. The similarity to the metanephric collecting duct suggests that the lineages of metanephric alpha-intercalated and principal cells may be closely related to those of the mesonephros.

H+ secretion in rabbit mesonephric collecting tubule

The mesonephros, the precursor of the metanephros, the definitive kidney, is the functional excretory organ in the 12- to 20-day-old rabbit fetus. It is believed to acidify allantoic fluid. To determine whether H+ excretion occurs in the distal nephron, we examined isolated perfused mesonephric collecting tubules by microcalorimetry and pH-sensitive fluorescent dyes. Collecting tubules secreted H+ (absorbed HCO3-) at rates twice those observed in the mature outer medullary collecting duct (OMCD) of the metanephric kidney. H+ secretion was not inhibited by ouabain (18.5 +/- 2.2 vs. 16.7 +/- 4.0 pmol.min-1.mm-1; n = 7, P = NS) but was reversibly inhibited by removing Cl- from the bathing solution (15.1 +/- 2.3 to -0.6 +/- 3.7 to 15.5 +/- 1.1 pmol.min-1.mm-1; n = 5, P < 0.05); luminal application of N-ethylmaleimide (NEM), an inhibitor of the H(+)-ATPase, also inhibited H+ secretion (n = 2). These results suggested that H+ secretion in the mesonephric collecting tubule is mediated by transporters similar to those of the OMCD. To test this hypothesis, we stained collecting tubules from 15-20 day embryos with 6-carboxyfluorescein (6-CF) diacetate to identify intercalated-like cells or perfused them with 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein acetoxymethyl ester (BCECF-AM) to measure intracellular pH (pHi). We found that 139 +/- 15 cells/mm concentrated 6-CF or BCECF, consistent with the phenotype of metanephric intercalated cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Age-dependent effects of CCK and devazepide in male and female rats

Peripheral administration of the brain/gut peptide cholecystokinin (CCK) has been demonstrated to inhibit food intake in a variety of species, and administration of the specific type A CCK receptor antagonist devazepide increases food intake in a variety of experimental paradigms. The potency of CCK to inhibit intake depends upon a variety of factors, but CCK is generally less potent under conditions of elevated food intake. At different developmental stages, rats' intake requirements differ as growth rates change. To determine whether CCK plays a variable role in the control of intake in rats of different ages, we examined the feeding-inhibitory effect of various doses of CCK and the feeding-enhancing potential of various doses of devazepide on glucose consumption (0.5 kcal/ml) in male and female rats at 45-70 and 110-130 days of age. CCK was more potent in older male and female rats than in younger rats, and inhibited intake in a dose-related fashion. In younger rats, the efficacy of CCK was attenuated and the inhibition was not dose related. Administration of devazepide had no effect on intake in younger rats of either sex, but significantly increased glucose consumption in the older rats. These data suggest that during a period of rapid growth and high levels of food intake relative to body weight, adolescent rats are relatively insensitive to exogenous CCK and endogenous CCK does not appear to play a significant role in controlling their intake.

Cholecystokinin inhibits gastric emptying and contracts the pyloric sphincter in rats by interacting with low affinity CCK receptor sites

The aim of these experiments was to characterize the receptor affinity state through which CCK produces pyloric contraction and inhibits gastric emptying in the rat using the novel CCK heptapeptide analog CCK-JMV-180. CCK-JMV-180 has been demonstrated to act as a functional agonist at high affinity pancreatic CCKA receptors but as a functional antagonist at CCKA low affinity receptors. CCK-8 (1, 3.2 and 10 nM) induced dose dependent tension increases in isolated pyloric segments. CCK-JMV-180 (3.2 microM) or vehicle failed to mimic this action when administered alone but blocked the ability of CCK-8 (3.2 nM) to induce tension increases. CCK-8 (2 micrograms/kg) also inhibited the gastric emptying of physiological saline. CCK-JMV-180 (320 and 1000 micrograms/kg) failed to inhibit emptying when administered alone but dose dependently antagonized CCK induced inhibition of gastric emptying. Thus, in both preparations CCK-JMV-180 acted as a functional CCK antagonist. This profile is consistent with the interpretation that the actions of CCK in pyloric contraction and the inhibition of gastric emptying are mediated through CCK's interactions with receptors functionally similar to pancreatic low affinity sites.

Pharmacological dissociation of responses to CCK and gastric loads in rat mechanosensitive vagal afferents

To identify the transduction mechanisms underlying gastric vagal afferent responses to gastric loads and cholecystokinin (CCK), we investigated the ability of specific CCK antagonists, acute pylorectomy, and cholinergic blockade to effect these vagal afferent responses. The CCK-B antagonist L-365,260 (10 pmol-1 nmol) failed to block the gastric vagal afferent response to gastric loads or 100 pmol CCK, while the CCK-A antagonist devazepide (100 pmol-100 nmol) competitively and dose dependently attenuated the response to CCK but not to gastric loads. Application of 100 nmol of the low-affinity CCK receptor antagonist CCK-JMV-180 also completely blocked the gastric vagal afferent response to 100 pmol CCK. Acute pylorectomy failed to block the gastric vagal afferent response to 100 pmol CCK or 2-ml gastric loads. Atropine sulfate administration (15 mg/rat) failed to block the gastric vagal afferent response to 100 pmol CCK or 2-ml gastric loads. These data suggest that 1) the vagal afferent response to CCK is mediated through CCK's interactions with vagal, rather than pyloric, CCK-A receptors, and 2) the vagal afferent responses to CCK and to gastric loads are mediated by dissociable, possibly independent, transduction mechanisms.

Inhibition of bicarbonate transport in peanut lectin-positive intercalated cells by a monoclonal antibody

Intercalated cells (ICC) of the collecting duct are believed to secrete acid (alpha-type) or HCO3 (beta-type). Although these two types of ICC are functionally mirror images of each other, several components in their cell membranes are clearly unique. As a first step in defining the molecular composition of beta-ICC membranes, we raised cell-specific monoclonal antibodies (MAb) against surface antigens. One of these MAb, designated B63, reacts with the apical membrane of peanut lectin agglutinin (PNA)-positive cells of the kidney cortex. B63-positive cells do not react with antibodies against band 3 (the basolateral C1/HCO3 exchanger) or ST.48, markers for alpha-ICC and principal cells, respectively. Despite a significant positive correlation between PNA and B63 staining intensities, determined by flow cytometry, these markers react with separate antigens, as indicated by competition studies and the different distribution of the two antigens. In addition to renal beta-ICC, B63 antigen is present in tissues that are involved in HCO3 secretion, such as the pancreas, salivary glands, and the small intestine, suggesting that it might play a role in HCO3 secretion. To test this hypothesis more directly, we tested the effect of MAb B63 on HCO3 secretion and on changes in intracellular pH (pHi) in isolated perfused cortical collecting ducts. Luminal Cl removal in the presence of luminal 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid resulted in a reversible increase in pHi. Luminal application of MAb B63 prevented this change in pHi. MAb B63 also significantly inhibited (by 37.7 +/- 7.3%) HCO3 secretion by isolated perfused tubules, whereas another MAb (MAb 601), which reacts with a separate antigen on beta-ICC, did not alter HCO3 secretion or pHi. These results indicate that B63 antigen plays an important role in HCO3 secretion: it might be either the apical anion exchanger of beta-ICC or an associated regulatory protein.

CCK elicits and modulates vagal afferent activity arising from gastric and duodenal sites

We have begun to identify and characterize the locations and response profiles of vagal afferent fibers sensitive to CCK in the rat upper gastrointestinal tract. We found gastric and duodenal vagal afferent fibers that respond to CCK and to intraluminal loads. CCK both sensitizes and amplifies the response to loads in these fibers but may do so through separate transduction mechanisms. Thus, meal-related signals arising from the presence of gastroduodenal loads and the release of endogenous CCK can be integrated at the level of the peripheral afferent vagus nerve. These findings are consistent with behavioral results, demonstrating that combinations of gastric loads and exogenous CCK are more effective in suppressing food intake than is either stimulus presented alone. Our findings that both gastric and duodenal vagal afferent fibers are sensitive to CCK suggest that meal-related CCK may act at a range of peripheral neural sites linking the upper gastrointestinal tract to the central nervous system substrates underlying the control of food intake. The mode of activation of gastric vagal afferent by endogenously released CCK may be an endocrine action of intestinally derived CCK. Alternatively, the novel finding of duodenal load-sensitive vagal afferents close to a site of CCK release provides a potential for local paracrine actions of endogenous CCK in the mediation of satiety.

Low pH enhances expression of carbonic anhydrase II by cultured rat inner medullary collecting duct cells

Carbonic anhydrase (CA) facilitates the secretion of protons from renal epithelia by catalyzing the buffering of hydroxyl ions by CO2. We have previously found that inner medullary collecting duct (IMCD) cells cultured from rat kidney secrete protons and express CA II. Incubation of IMCD cells in acidic medium for 48 h has been shown to stimulate the secretion of protons by a protein synthesis-dependent process. To establish whether CA II might be involved in this process, IMCD cells were exposed to incubation media supplemented with 10(-7) M deoxycorticosterone acetate, pH 7.0 (acid) or pH 7.7 (control) for 48 h, and CA II mRNA and protein were quantitated. Part of the CA II cDNA was obtained by reverse transcription of total RNA from rat kidney followed by amplification using oligonucleotide primers derived from conserved areas in the coding regions of human, mouse, and chick CA II cDNAs in a polymerase chain reaction. By Northern analysis, steady-state levels of CA II mRNA from acid-incubated cells showed an increase of 80% compared with controls and 70% when expressed relative to a housekeeping mRNA, beta-actin. Western blot analysis using a human antibody to CA II showed an approximate doubling of CA II protein after acid incubation. By immunofluorescence microscopy, the domes of acid-incubated IMCD cells contained considerably more CA II-stained cells than found in control cultures. Thus incubation of IMCD cells in acid medium stimulates the expression of CA II mRNA and protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic acidosis stimulates carbonic anhydrase activity in rabbit proximal tubule and medullary collecting duct

Both membrane-bound carbonic anhydrase (CA) (isozyme type IV) and cytosolic CA (type II) activities enhance urinary acidification. We have previously shown that chronic metabolic acidosis (CMA) accomplished by NH4Cl loading with food restriction induces soluble CA activity in rabbit renal cortical homogenates. The present study was designed to assess the effect of CMA on the activity of CA isozymes in cortical and outer medullary homogenates, as well as in major proton-secreting segments of the kidney. Segments were microdissected from proximal convoluted tubules (PCT) proximal straight tubules, cortical collecting ducts, and outer medullary collecting ducts (OMCD). Total CA activity was measured by a colorimetric endpoint method, and CA IV activity was assessed from the sodium dodecyl sulfate-resistant hydratase activity. In controls, CA IV activity accounted for 3% of total CA activity in tissue homogenates. CMA induced a threefold increase in CA IV activity in cortical homogenates, in the absence of renal or tubular hypertrophy. In the PCT, CMA induced a 78% increase in total CA activity, which comprised a 178% increase in CA IV activity, and a 58% increase in CA II activity. In the OMCD, CMA induced a 53% increase in total CA (probably CA II) activity. We conclude that CMA induces CA activity in the PCT (CA II and CA IV) and the OMCD (most likely CA II) of adult rabbit kidneys. The induction of CA activity accompanies the increase in urinary acidification observed in CMA.