Regulation of the human NBC3 Na+/HCO3- cotransporter by carbonic anhydrase II and PKA

Human NBC3 is an electroneutral Na⁺/HCO₃^– cotransporter expressed in heart, skeletal muscle, and kidney in which it plays an important role in HCO₃^– metabolism. Cytosolic enzyme carbonic anhydrase II (CAII) catalyzes the reaction CO₂ + H₂O HCO₃^– + H⁺ in many tissues. We investigated whether NBC3, like some Cl^–/HCO₃^– exchange proteins, could bind CAII and whether PKA could regulate NBC3 activity through modulation of CAII binding. CAII bound the COOH-terminal domain of NBC3 (NBC3Ct) with K_d = 101 nM; the interaction was stronger at acid pH. Cotransfection of HEK-293 cells with NBC3 and CAII recruited CAII to the plasma membrane. Mutagenesis of consensus CAII binding sites revealed that the D1135-D1136 region of NBC3 is essential for CAII/NBC3 interaction and for optimal function, because the NBC3 D1135N/D1136N retained only 29 ± 22% of wild-type activity. Coexpression of the functionally dominant-negative CAII mutant V143Y with NBC3 or addition of 100 µM 8-bromoadenosine to NBC3 transfected cells reduced intracellular pH (pH_i) recovery rate by 31 ± 3, or 38 ± 7%, respectively, relative to untreated NBC3 transfected cells. The effects were additive, together decreasing the pH_i recovery rate by 69 ± 12%, suggesting that PKA reduces transport activity by a mechanism independently of CAII. Measurements of PKA-dependent phosphorylation by mass spectroscopy and labeling with [-³²P]ATP showed that NBC3Ct was not a PKA substrate. These results demonstrate that NBC3 and CAII interact to maximize the HCO₃^– transport rate. Although PKA decreased NBC3 transport activity, it did so independently of the NBC3/CAII interaction and did not involve phosphorylation of NBC3Ct. pH regulation; bicarbonate transport; metabolon     

Three distinct mechanisms of HCO3- secretion in rat distal colon

HCO₃^– secretion has long been recognized in the mammalian colon, but it has not been well characterized. Although most studies of colonic HCO₃^– secretion have revealed evidence of lumen Cl^– dependence, suggesting a role for apical membrane Cl^–/HCO₃^– exchange, direct examination of HCO₃^– secretion in isolated crypt from rat distal colon did not identify Cl^–-dependent HCO₃^– secretion but did reveal cAMP-induced, Cl^–-independent HCO₃^– secretion. Studies were therefore initiated to determine the characteristics of HCO₃^– secretion in isolated colonic mucosa to identify HCO₃^– secretion in both surface and crypt cells. HCO₃^– secretion was measured in rat distal colonic mucosa stripped of muscular and serosal layers by using a pH stat technique. Basal HCO₃^– secretion (5.6 ± 0.03 µeq·h^–1·cm^–2) was abolished by removal of either lumen Cl^– or bath HCO₃^–; this Cl^–-dependent HCO₃^– secretion was also inhibited by 100 µM DIDS (0.5 ± 0.03 µeq·h^–1·cm^–2) but not by 5-nitro-3-(3-phenylpropyl-amino)benzoic acid (NPPB), a Cl^– channel blocker. 8-Bromo-cAMP induced Cl^–-independent HCO₃^– secretion (and also inhibited Cl^–-dependent HCO₃^– secretion), which was inhibited by NPPB and by glibenclamide, a CFTR blocker, but not by DIDS. Isobutyrate, a poorly metabolized short-chain fatty acid (SCFA), also induced a Cl^–-independent, DIDS-insensitive, saturable HCO₃^– secretion that was not inhibited by NPPB. Three distinct HCO₃^– secretory mechanisms were identified: 1) Cl^–-dependent secretion associated with apical membrane Cl^–/HCO₃^– exchange, 2) cAMP-induced secretion that was a result of an apical membrane anion channel, and 3) SCFA-dependent secretion associated with an apical membrane SCFA/HCO₃^– exchange. chloride/bicarbonate exchange; short-chain fatty acid/bicarbonate exchange; anion channel; pH stat     

Expression and localization of Na(+)-HCO(3)(-) cotransporter in bovine corneal endothelium

Functional studiessupport the presence of the Na⁺-HCO₃cotransporter (NBC) in corneal endothelium and possibly cornealepithelium; however, molecular identification and membrane localizationhave not been reported. To test whether NBC is expressed in bovine cornea, Western blotting was performed, which showed a single band at~130 kDa for freshly isolated and cultured endothelial cells, but noband for epithelium. Two isoforms of NBC have recently been cloned inkidney (kNBC) and pancreas (pNBC). RT-PCR was run using cultured andfresh bovine corneal endothelial and fresh corneal epithelial total RNAand specific primers for kNBC and pNBC. RT-PCR analysis for pNBC waspositive in endothelium and weak in epithelium. The RT-PCR product wassubcloned and confirmed as pNBC by sequencing. No specific bands forkNBC were obtained from corneal cells. Indirect immunofluorescence andconfocal microscopy indicated that NBC locates predominantly to thebasolateral membrane in corneal endothelial cells. Furthermore,Na⁺-dependent HCO₃ fluxes andHCO₃-dependent cotransport with Na⁺ wereelicited only from the basolateral side of corneal endothelial cells.Therefore, we conclude that pNBC is present in the basolateral membraneof both fresh and cultured bovine corneal endothelium and weaklyexpressed in the corneal epithelium.

     

Na+-dependent HCO3- uptake into the rat choroid plexus epithelium is partially DIDS sensitive

Several studies suggest the involvement of Na⁺ and HCO₃^– transport in the formation of cerebrospinal fluid. Two Na⁺-dependent HCO₃^– transporters were recently localized to the epithelial cells of the rat choroid plexus (NBCn1 and NCBE), and the mRNA for a third protein was also detected (NBCe2) (Praetorius J, Nejsum LN, and Nielsen S. Am J Physiol Cell Physiol 286: C601–C610, 2004). Our goal was to immunolocalize the NBCe2 to the choroid plexus by immunohistochemistry and immunogold electronmicroscopy and to functionally characterize the bicarbonate transport in the isolated rat choroid plexus by measurements of intracellular pH (pH_i) using a dual-excitation wavelength pH-sensitive dye (BCECF). Both antisera derived from COOH-terminal and NH₂-terminal NBCe2 peptides localized NBCe2 to the brush-border membrane domain of choroid plexus epithelial cells. Steady-state pH_i in choroidal cells increased from 7.03 ± 0.02 to 7.38 ± 0.02 (n = 41) after addition of CO₂/HCO₃^– into the bath solution. This increase was Na⁺ dependent and inhibited by the Cl^– and HCO₃^– transport inhibitor DIDS (200 µM). This suggests the presence of Na⁺-dependent, partially DIDS-sensitive HCO₃^– uptake. The pH_i recovery after acid loading revealed an initial Na⁺ and HCO₃^–-dependent net base flux of 0.828 ± 0.116 mM/s (n = 8). The initial flux in the presence of CO₂/HCO₃^– was unaffected by DIDS. Our data support the existence of both DIDS-sensitive and -insensitive Na⁺- and HCO₃^–-dependent base loader uptake into the rat choroid plexus epithelial cells. This is consistent with the localization of the three base transporters NBCn1, Na⁺-driven Cl^– bicarbonate exchanger, and NBCe2 in this tissue. bicarbonate metabolism; BCECF; cerebrospinal fluid; acid/base transport; ammonium prepulse     

Nongenomic regulation by aldosterone of the epithelial NHE3 Na(+)/H(+) exchanger

The relevance of nongenomic pathways to regulation of epithelial function by aldosterone is poorly understood. Recently, we demonstrated that aldosterone inhibits transepithelial HCO₃^– absorption in the renal medullary thick ascending limb (MTAL) through a nongenomic pathway. Here, we examined the transport mechanism(s) responsible for this regulation, focusing on Na⁺/H⁺ exchangers (NHE). In the MTAL, apical NHE3 mediates H⁺ secretion necessary for HCO₃^– absorption; basolateral NHE1 influences HCO₃^– absorption by regulating apical NHE3 activity. In microperfused rat MTALs, the addition of 1 nM aldosterone rapidly decreased HCO₃^– absorption by 30%. This inhibition was unaffected by three maneuvers that inhibit basolateral Na⁺/H⁺ exchange and was preserved in MTALs from NHE1 knockout mice, ruling out the involvement of NHE1. In contrast, exposure to aldosterone for 15 min caused a 30% decrease in apical Na⁺/H⁺ exchange activity over the intracellular pH range from 6.5 to 7.7, due to a decrease in V_max. Inhibition of HCO₃^– absorption by aldosterone was not affected by 0.1 mM lumen Zn²⁺ or 1 mM lumen DIDS, arguing against the involvement of an apical H⁺ conductance or apical K⁺-HCO₃^– cotransport. These results demonstrate that aldosterone inhibits HCO₃^– absorption in the MTAL through inhibition of apical NHE3, and identify NHE3 as a target for nongenomic regulation by aldosterone. Aldosterone may influence a broad range of epithelial transport functions important for extracellular fluid volume and acid-base homeostasis through direct regulation of this exchanger. thick ascending limb; acid-base transport; epithelial Na⁺ transport; kidney     

Plasmalemma Transport of HCO3- and OH- in Chara corallina: Non-antiporter Systems

An experimental system was designed to test the obligate couplingbetween HCO₃^– and OH^– fluxes (i. e. a ‘Mitchell-type’antiporter) proposed by Lucas and Smith (1973). The resultsof these experiments demonstrated categorically that the OH^–efflux process can function in the absence of exogenous HCO₃^–at the actual OH^– efflux site. Hence, the obligate couplinghypothesis is invalid. It is proposed that HCO₃^– and OH^–are transported across the plasmalemma ‘independently’,on quite distinct carriers. It is possible, therefore, thatthese fluxes contribute towards determining the electrical propertiesof this membrane when the bathing solution pH value is 6.5.It was also found that HCO₃^– can be transported acrossthe dark segment of a partly illuminated cell. The observedrates were always much less than those obtained in the illuminatedcell segment. The significance of this result is discussed.     

Expression and localization of rat NBC4c in liver and renal uroepithelium

Previous studies provided functional evidence for electrogenic Na⁺-HCO₃^– cotransport in hepatocytes and in intrahepatic bile duct cholangiocytes. The molecular identity of the transporters mediating electrogenic sodium-bicarbonate cotransport in the liver is currently unknown. Of the known electrogenic Na⁺-HCO₃^– cotransporters (NBC1 and NBC4), we previously showed that NBC4 mRNA is highly expressed in the liver. In the present study, we performed RT-PCR, immunoblotting, and immunohistochemistry to characterize the expression pattern of NBC4 in rat liver and kidney. For immunodetection, a polyclonal antibody against rat NBC4 was generated and affinity purified. Of the known human NBC4 variants, only the rat NBC4c ortholog was detected by RT-PCR in rat liver, and the molecular mass of the NBC4c protein was 145 kDa. NBC4c protein was expressed in hepatocytes and in the cholangiocytes lining the intrahepatic bile ducts. In hepatocytes, NBC4c was localized to the basolateral plasma membrane, whereas intrahepatic cholangiocytes stained apically. The NBC1 electrogenic sodium cotransporter variants kNBC1 and pNBC1 were not detected by immunoblotting and immunohistochemistry in rat liver. The pattern of localization of NBC4c in the liver suggests that the cotransporter plays a role in mediating Na⁺-HCO₃^– cotransport in hepatocytes and intrahepatic cholangiocytes. Unlike the liver, the rat kidney expressed electrogenic sodium-bicarbonate cotransporter proteins kNBC1 and NBC4c. In kidney, NBC4c also had a molecular mass of 145 kDa and was immunolocalized to uroepithelial cells lining the renal pelvis, where the cotransporter may play an important role in protecting the renal parenchyma from alterations in urine pH. bicarbonate; transport; electrogenic     

Distribution of sodium transporters and aquaporin-1 in the human choroid plexus

The choroid plexus epithelium secretes electrolytes and fluid in the brain ventricular lumen at high rates. Several channels and ion carriers have been identified as likely mediators of this transport in rodent choroid plexus. This study aimed to map several of these proteins to the human choroid plexus. Immunoperoxidase-histochemistry was employed to determine the cellular and subcellular localization of the proteins. The water channel, aquaporin (AQP) 1, was predominantly situated in the apical plasma membrane domain, although distinct basolateral and endothelial immunoreactivity was also observed. The Na⁺-K⁺-ATPase ₁-subunit was exclusively localized apically in the human choroid plexus epithelial cells. Immunoreactivity for the Na⁺-K⁺-2Cl^– cotransporter, NKCC1, was likewise confined to the apical plasma membrane domain of the epithelium. The Cl^–/HCO₃^– exchanger, AE2, was localized basolaterally, as was the Na⁺-dependent Cl^–/HCO₃^– exchanger, NCBE, and the electroneutral Na⁺-HCO₃^– cotransporter, NBCn1. No immunoreactivity was found toward the Na⁺-dependent acid/base transporters NHE1 or NBCe2. Hence, the human choroid plexus epithelium displays an almost identical distribution pattern of water channels and Na⁺ transporters as the rat and mouse choroid plexus. This general cross species pattern suggests central roles for these transporters in choroid plexus functions such as cerebrospinal fluid production. immunohistochemistry; metabolism; cerebrospinal fluid secretion     

Protein kinase C mediates the inhibitory effect of substance P on HCO3- secretion from guinea pig pancreatic ducts

The inhibitory control of pancreatic ductal HCO₃^– secretion may be physiologically important in terms of limiting the hydrostatic pressure developed within the ducts and in terms of switching off pancreatic secretion after a meal. Substance P (SP) inhibits secretin-stimulated HCO₃^– secretion by modulating a Cl^–-dependent HCO₃^– efflux step at the apical membrane of the duct cell (Hegyi P, Gray MA, and Argent BE. Am J Physiol Cell Physiol 285: C268–C276, 2003). In the present study, we have shown that SP is present in periductal nerves within the guinea pig pancreas, that PKC mediates the effect of SP, and that SP inhibits an anion exchanger on the luminal membrane of the duct cell. Secretin (10 nM) stimulated HCO₃^– secretion by sealed, nonperfused, ducts about threefold, and this effect was totally inhibited by SP (20 nM). Phorbol 12,13-dibutyrate (PDBu; 100 nM), an activator of PKC, reduced basal HCO₃^– secretion by 40% and totally blocked secretin-stimulated secretion. In addition, bisindolylmaleimide I (1 nM to 1 µM), an inhibitor of PKC, relieved the inhibitory effect of SP on secretin-stimulated HCO₃^– secretion and also reversed the inhibitory effect of PDBu. Western blot analysis revealed that guinea pig pancreatic ducts express the -, _I-, -, -, -, -, -, and µ-isoforms of PKC. In microperfused ducts, luminal H₂DIDS (0.5 mM) caused intracellular pH to alkalinize and, like SP, inhibited basal and secretin-stimulated HCO₃^– secretion. SP did not inhibit secretion further when H₂DIDS was present in the lumen, suggesting that SP and H₂DIDS both inhibit the activity of an anion exchanger on the luminal membrane of the duct cell. pancreas; Cl^–/HCO₃^– exchanger; inhibition; epithelium     

NKCC1 and NHE1 are abundantly expressed in the basolateral plasma membrane of secretory coil cells in rat, mouse, and human sweat glands

In isolated sweat glands, bumetanide inhibits sweat secretion. The mRNA encoding bumetanide-sensitive Na⁺-K⁺-Cl^– cotransporter (NKCC) isoform 1 (NKCC1) has been detected in sweat glands; however, the cellular and subcellular protein localization is unknown. Na⁺/H⁺ exchanger (NHE) isoform 1 (NHE1) protein has been localized to both the duct and secretory coil of human sweat duct; however, the NHE1 abundance in the duct was not compared with that in the secretory coil. The aim of this study was to test whether mRNA encoding NKCC1, NKCC2, and Na⁺-coupled acid-base transporters and the corresponding proteins are expressed in rodent sweat glands and, if expressed, to determine the cellular and subcellular localization in rat, mouse, and human eccrine sweat glands. NKCC1 mRNA was demonstrated in rat palmar tissue, including sweat glands, using RT-PCR, whereas NKCC2 mRNA was absent. Also, NHE1 mRNA was demonstrated in rat palmar tissue, whereas NHE2, NHE3, NHE4, electrogenic Na⁺-HCO₃^– cotransporter 1 NBCe1, NBCe2, electroneutral Na⁺-HCO₃^– cotransporter NBCn1, and Na⁺-dependent Cl^–/HCO₃^– exchanger NCBE mRNA were not detected. The expression of NKCC1 and NHE1 proteins was confirmed in rat palmar skin by immunoblotting, whereas NKCC2, NHE2, and NHE3 proteins were not detected. Immunohistochemistry was performed using sections from rat, mouse, and human palmar tissue. Immunoperoxidase labeling revealed abundant expression of NKCC1 and NHE1 in the basolateral domain of secretory coils of rat, mouse, and human sweat glands and low expression was found in the coiled part of the ducts. In contrast, NKCC1 and NHE1 labeling was absent from rat, mouse, and human epidermis. Immunoelectron microscopy demonstrated abundant NKCC1 and NHE1 labeling of the basolateral plasma membrane of mouse sweat glands, with no labeling of the apical plasma membranes or intracellular structures. The basolateral NKCC1 of the secretory coils of sweat glands would most likely account for the observed bumetanide-sensitive NaCl secretion in the secretory coils, and the basolateral NHE1 is likely to be involved in Na⁺-coupled acid-base transport. bumetanide; eccrine glands; immunohistochemistry; immunoblotting     

Immunocytochemical localization of Na+-HCO3- cotransporters and carbonic anhydrase dependence of fluid transport in corneal endothelial cells

In corneal endothelium, there is evidence for basolateral entry of HCO(3)(-) into corneal endothelial cells via Na(+)-HCO(3)(-) cotransporter (NBC) proteins and for net HCO(3)(-) flux from the basolateral to the apical side. However, how HCO(3)(-) exits the cells through the apical membrane is unclear. We determined that cultured corneal endothelial cells transport HCO(3)(-) similarly to fresh tissue. In addition, Cl(-) channel inhibitors decreased fluid transport by at most 16%, and inhibition of membrane-bound carbonic anhydrase IV by benzolamide or dextran-bound sulfonamide decreased fluid transport by at most 29%. Therefore, more than half of the fluid transport cannot be accounted for by anion transport through apical Cl(-) channels, CO(2) diffusion across the apical membrane, or a combination of these two mechanisms. However, immunocytochemistry using optical sectioning by confocal microscopy and cryosections revealed the presence of NBC transporters in both the basolateral and apical cell membranes of cultured bovine corneal endothelial cells and freshly isolated rabbit endothelia. This newly detected presence of an apical NBC transporter is consistent with its being the missing mechanism sought. We discuss discrepancies with other reports and provide a model that accounts for the experimental observations by assuming different stoichiometries of the NBC transport proteins at the basolateral and apical sides of the cells. Such functional differences might arise either from the expression of different isoforms or from regulatory factors affecting the stoichiometry of a single isoform.     

Effects of Ammonia and Methylamine on Cl- Transport and on the pH Changes and Circulating Electric Currents Associated with HCO3- Assimilation in Chara corallina

Low concentrations of ammonia and methylamine greatly increaseCl^– influx into Chara corallina. Both amines have theirmaximum effect at pH 6.5–7.5. The amine stimulation ofCl^– influx is small below about pH 5.5. Above pH 8.5 theremay be inhibition of influx by amines. Concentrations of 10–25µM ammonia are sufficient to cause the maximum stimulationof Cl^– influx; the corresponding methylamine concentrationsare 0.1–0.2 mM. It is concluded that entry of amine cations(NH₄^$ and CH₃NH₃^$), rather than unionized bases (NH₃ and CH₃NH₂),causes Cl^– transport to be increased. Increases in rates of Cl^– transport are not necessarilyaccompanied by effects on HCO₃^$ assimilation and OH^– efflux.Measurements of localized pH differences at the cell surfaceand of circulating electric currents in the bathing solutionshow that these phenomena are only significantly affected byammonia at or above 50 µM and by methylamine at or above1.0 mM. The significance of the effects of amines is assessedin relation to current ideas about transport of Cl^–, HCO₃^–,and OH^–.     

Na+:HCO(3-) cotransporters (NBC): cloning and characterization

The sodium bicarbonate cotransporter (NBC1) is essential for bicarbonate transport across plasma membranes in epithelial and nonepithelial cells. The direction of the NaHCO₃ movement in secretory epithelia is opposite to that in reabsorptive epithelia. In secretory epithelia (such as pancreatic duct cells) NBC is responsible for the transport of bicarbonate from blood to the cell for eventual secretion at the apical membrane. In reabsorptive epithelia (such as kidney proximal tubule cells) NBC is responsible for the reabsorption of bicarbonate from cell to the blood. In nonepithelial cells this transporter is mainly involved with cell pH regulation. Recent molecular cloning experiments have identified the existence of four NBC isoforms (NBC1, 2, 3 and 4) and two NBC-related proteins AE4 and NCBE (Anion Exchanger 4 and Na-dependent Chloride-Bicarbonate Exchanger). All but AE4 are presumed to mediate the cotransport of Na⁺ and HCO₃ ⁻ under normal conditions and may be functionally altered in certain pathologic states. NBC1 shows a limited tissue expression pattern, is electrogenic and plays an important role in bicarbonate reabsorption in kidney proximal tubule. In addition to the kidney, NBC1 is expressed in pancreatic duct cells, is activated by cystic fibrosis transmembrane conductance regulator (CFTR) and plays an important role in HCO₃ ⁻ secretion. NBC2 and NBC3 have a wider tissue distribution than NBC1, are electroneutral, and are involved with cell pH regulation. The characterization of NBC4 is incomplete. The NBC-related protein called NCBE mediates Na-dependent, Cl⁻/Bicarbonate Exchange. The purpose of this review is to summarize recent advances on the cloning of NBC isoforms and related proteins and their role and regulation in physiologic and pathologic states. Received: 26 February 2001/Revised: 14 May 2001     

Analogue Inhibition of the Active HCO-3 Transport Site in the Characean Plasma Membrane

Competitive inhibition of the HCO^–₃ transport site, atthe plasmalemma of Chara coraUina, by the CO^2–₃ ion isdemonstrated. This CO^2–₃ inhibition was used to demonstratethat HCO^–₃ ions enter the cell by facilitated ‘diffusion’when the HCO^–₃ transport system has been inactivated bytreatment with 10 mM K⁺. Use of CO^2–₃ as a HCO^–₃analogue is limited, however, because of the necessity to employsolutions of high pH. Inhibition was not observed in the presenceof a range of organic and inorganic acid anions. These resultsdemonstrate the stereo-specific nature of the HCO^–₃ bindingsite. A variety of amino compounds were found to inhibit H¹⁴CO^–₃influx. Inhibition appeared to be competitive, being completelyrelieved at higher substrate (HCO^–₃) concentrations. Asimple correlation was not found between the degree of inhibitionand the concentration of neutral base. A combination of thepresence of neutral base and experimental pH values of at least8·0 was required to produce the reactive species thatinhibited HCO^–₃ transport. This species is consideredto be the amino carbamate. These results are discussed withrespect to further HCO^–₃ analogue experiments.     

Transport and Fixation of Inorganic Carbon during Photosynthesis in Cells of Anabaena Grown under Ordinary Air: III. Some Characteristics of the HCO3--Transport System in Cells Grown under Ordinary Air

In cells of cyanobacterium Anabaena variabilis grown under ordinaryair (low-CO₂ cells), the transport of both CO₂ and HCO₃^–was significantly enhanced by Na⁺. This effect was pronouncedas the external pH increased. When low-CO₂ cells were treatedwith an inhibitor of carbonic anhydrase (CA), only CO₂ transportbut not HCO₃^– transport, was inhibited. The initial rateof photosynthetic carbon fixation as a function of the concentrationof internal inorganic carbon (IC) was practically the same irrespectiveof whether CO₂ or HCO₃^– was externally supplied. Theseresults suggest that IC is actively transported through theplasma membrane in a form of HCO₃^– probably by some transporterand that the transmembrane Na⁺ gradient is involved in thisIC transport system. Free CO₂ may be hydrated by CA to HCO₃^–and then transported to the cells by this transporter. On the other hand, CO₂ is actively taken up by cells grown withair containing 5% CO₂ (high-CO₂ cells) though the enhancingeffect of Na⁺ was much smaller in high- CO₂ cells than in low-CO₂cells. The initial rate of fixation as a function of internal IC concentrationindicated that the rate of the carboxylation reaction of accumulatedIC is higher in I0W-CO₂ cells than in high-CO₂ cells. The studieswith ethoxyzolamide indicated that even in low-CO₂ cells, CAdoes not function inside Anabaena cells. These results suggestthat inside the low-CO₂ cells of Anabaena, some mediator(s)facilitates the transport of IC to RuBPCase. (Received January 23, 1987; Accepted April 24, 1987)     

Expression, localization, and functional evaluation of CFTR in bovine corneal endothelial cells

HCO-dependentfluid secretion by the corneal endothelium controls corneal hydrationand maintains corneal transparency. Recently, it has been shown thatmRNA for the cystic fibrosis transmembrane conductance regulator (CFTR) is expressed in the corneal endothelium; however, protein expression, functional localization, and a possible role in HCO transport have not been reported. Immunoblotting for CFTR showed asingle band at ~170 kDa for both freshly isolated and primary cultures of bovine corneal endothelial cells. Indirectimmunofluorescence confocal microscopy indicated that CFTR locates tothe apical membrane. Relative changes in apical and basolateralchloride permeability were estimated by measuring the rate offluorescence quenching of the halide-sensitive indicator6-methoxy-N-ethylquinolinium iodide during Clinflux in the absence and presence of forskolin (FSK). Apical andbasolateral Cl permeability increased 10- and 3-fold,respectively, in the presence of 50 µM FSK. FSK-activated apicalchloride permeability was unaffected by H₂DIDs (250 µM);however, 5-nitro-2-(3-phenylpropyl-amino)benzoic acid (NPPB; 50 µM) and glibenclamide (100 µM) inhibited activated Clfluxes by 45% and 30%, respectively. FSK-activated basolateral Cl permeability was insensitive to NPPB, glibenclamide,or furosemide but was inhibited 80% by H₂DIDS.HCO permeability was estimated by measuring changesin intracellular pH in response to quickly lowering bath[HCO]. FSK (50 µM) increased apicalHCO permeability by twofold, which was inhibited42% by NPPB and 65% by glibenclamide. BasolateralHCO permeability was unaffected by FSK. Genistein(50 µM) significantly increased apical HCO andCl permeability by 1.8- and 16-fold, respectively. When50 µM genistein was combined with 50 µM FSK, there was no furtherincrease in Cl permeability; however,HCO permeability was reduced to the control level.In summary, we conclude that CFTR is present in the apical membrane ofbovine corneal endothelium and could contribute to transendothelialCl and HCO transport. Furthermore,there is a cAMP-activated Cl pathway on the basolateralmembrane that is not CFTR.

     

Apical and basolateral CO2-HCO-3 permeability in cultured bovine corneal endothelial cells

Corneal endothelial function is dependent onHCO₃ transport. However, the relativeHCO₃ permeabilities of the apical andbasolateral membranes are unknown. Using changes in intracellular pHsecondary to removingCO₂-HCO₃ (at constant pH) or removing HCO₃alone (at constant CO₂) fromapical or basolateral compartments, we determined the relative apicaland basolateral HCO₃ permeabilities and their dependencies on Na⁺ andCl. Removal ofCO₂-HCO₃from the apical side caused a steady-state alkalinization (+0.08 pHunits), and removal from the basolateral side caused an acidification(0.05 pH units). Removal ofHCO₃ at constantCO₂ indicated that the basolateralHCO₃ fluxes were about three to fourtimes the apical fluxes. Reducing perfusateNa⁺ concentration to 10 mM had noeffect on apical flux but slowed basolateralHCO₃ flux by one-half. In the absence of Cl, there was anapparent increase in apical HCO₃ fluxunder constant-pH conditions; however, no net change could be measuredunder constant-CO₂ conditions.Basolateral flux was slowed ~30% in the absence ofCl, but the net flux wasunchanged. The steady-state alkalinization after removal ofCO₂-HCO₃apically suggests that CO₂diffusion may contribute to apicalHCO₃ flux through the action of amembrane-associated carbonic anhydrase. Indeed, apicalCO₂ fluxes were inhibited by theextracellular carbonic anhydrase inhibitor benzolamide and partiallyrestored by exogenous carbonic anhydrase. The presence ofmembrane-bound carbonic anhydrase (CAIV) was confirmed byimmunoblotting. We conclude that theNa⁺-dependent basolateralHCO₃ permeability is consistent withNa⁺-nHCO₃cotransport. Changes inHCO₃ flux in the absence ofCl are most likely due toNa⁺-nHCO₃cotransport-induced membrane potential changes that cannot bedissipated. Apical HCO₃ permeabilityis relatively low, but may be augmented byCO₂ diffusion in conjunction witha CAIV.

     

Interactions of NH4+ and L-glutamate with NO3- transport processes of non-mycorrhizal Fagus sylvatica roots

The processes of NO₃^– uptake and transport and the effectsof NH₄⁺ or L-glutamate on these processes were investigatedwith excised non-mycorrhizal beech (Fagus sylvatica L.) roots.NO₃^– net uptake followed uniphasic Michaelis-Menten kineticsin a concentration range of 10µM to 1 mM with an apparentK_m of 9.2 µM and a V_max of 366 nmol g^–1 FW h^–1.NH₄⁺, when present in excess to NO₃^–, or 10 mM L-glutamateinhibited the net uptake of NO₃^– Apparently, part of NO₃^–taken up was loaded into the xylem. Relative xylem loading ofNO₃^– ranged from 3.21.6 to 6.45.1% of NO₃^– netuptake. It was not affected by treatment with NH₄⁺ or L-glutamate.¹⁶N/¹³N double labelling experiments showed that NO₃^–efflux from roots increased with increasing influx of NO₃^–and, therefore, declined if influx was reduced by NH₄⁺ or L-glutamateexposure. From these results it is concluded that NO₃^–net uptake by non-mycorrhizal beech roots is reduced by NH₄⁺or L-glutamate at the level of influx and not at the level ofefflux. Key words: Nitrate transport, net uptake, influx, efflux, ammonium, Fagus, Fagaceae     

Further Characteristics of Salt-Dependent Bicarbonate Use by the Seagrass Zostera muelleri

Millhouse, J. and Strother, S. 1987. Further characteristicsof salt-dependent bicarbonate use by the seagrass Zostera muelleri.—J.exp. Bot. 38: 1055–1068. The contribution of HCO^–₃to photosynthetic O₂ evolutionin the seagrass Zostera muelleri Irmisch ex Aschers. increasedwith increasing salinity of the bathing seawater when the inorganiccarbon concentration was kept constant. K_1/2 (seawater salts)for HCO^–₃ -dependent photosynthesis was 66% of seawatersalinity. Both short- and long-term pretreatment at low salinitiesstimulated photosynthesis in full strength seawater. Twentyfour hours pre-incubation of seagrass plants in 3·0 molm^–3 NaHCO₃ resulted in increased photosynthesis at allsalinities, apparently due to stimulation of HCO^–₃ use(K_1/2 (seawater salts) = 26%). V_max (HCO^–₃) was not affectedby low salinity pretreatment. The kinetics of HCO^–₃ stimulationby the major seawater cations was investigated. Ca²⁺ was themost effective cation with the highest V_max (HCO^–₃) andwith K_1/2(Ca²⁺) = 14 mol m^–3. Mg²⁺ was also very effectiveat less than 50 mol m^–3 but higher concentrations wereinhibitory. This inhibition cannot be accounted for solely byprecipitation of MgCO₃. Na⁺ and K⁺ were both capable of stimulatingHCO^–₃ use. Stimulation was in two distinct parts. Up to500 mol m^–3, both citrate and chloride salts gave similarresults (K_1/2(Na⁺) 81 mol m^–3, V_max(HCO^–₃) 0·26µmol O₂ mg^–1 chl min^–1), but use of citratesalts above 500 mol m^–2 caused a second stimulation ofHCO^–₃ use (K_1/2(Na⁺) 830 mol m^–3, V_max(HCO^–₃)0·68 µmol O₂ mg^–1 chl min^–1). V_max(HCO^–₃)for the second-phase Na⁺ or K⁺ stimulation was of the same orderas for Ca²⁺-stimulated HCO^–₃ use. To further characterizesalt-dependent HCO^–₃ use, the sensitivity of photosynthesisto Tris and TES buffers was investigated. The effects of Trisappear to be due to the action of Tris⁺ causing stimulationof HCO^–₃ -dependent photosynthesis in the absence of salt,but inhibition of HCO^–₃ use in saline media. TES has noeffect on photosynthesis. External carbonic anhydrase, althoughimplicated in salt-dependent HCO^–₃ use in Z. muelleri,could not be detected in whole leaves. Key words: Zostera muelleri, HCO^–₃ use, salinity     

The Permeability of Ammonia, Methylamine and Ethylamine in the Charophyte Chara corallina (C. australis)

Ritchie, R. J. 1987. The permeability of ammonia, methylamineand ethylamine in the charophyte Chara corallina (C. australis).—J.exp. Bot. 38: 67–76 The permeabilities of the amines, ammonia (NH₃), methylamine(CH₃NH₂) and ethylamine (CH₃CH₂NH₂) in the giant-celled charophyteChara corallina (C. australis) R.Br. have been measured andcompared. The permeabilities were corrected for uptake fluxesof the amine cations. Based on net uptake rates, the permeabilityof ammonia was 6?4?0?93 µm s^–1 (n = 38). The permeabilitiesof methylamine and ethylamine were measured in net and exchangeflux experiments. The permeabilities of methylamine were notsignificantly different in net and exchange experiments, norto that of ammonia (P_methylamine = 6?0?0?49 µm s^–1(n = 44)). In net flux experiments the apparent permeabilityof ethylamine was slightly greater than that of ammonia andmethylamine (P_{ethylamine, net} = 8?4?1?2 µm s^–1 (n= 40)) but the permeability of ethylamine based on exchangeflux data was significantly higher (P_{ethylamine, exchange} =14?1?2 µm s^–1 (n = 20)). Methylamine can be validlyused as an ammonium analogue in permeability studies in Chara. The plasmalemma of Chara has acid and alkaline bands; littlediffusion of uncharged amines would occur across the acid bands.The actual permeability of amines across the alkaline bandsis probably about twice the values quoted above on a whole cellbasis i.e. the permeability of ammonia across the permeablepart of the plasmalemma is probably about 12 µm s^–1. Key words: Chara, permeability, ammonia, methylamine