Splice Cassette II of Na+,HCO3? Cotransporter NBCn1 (slc4a7) Interacts with Calcineurin A: IMPLICATIONS FOR TRANSPORTER ACTIVITY AND INTRACELLULAR pH CONTROL DURING RAT ARTERY CONTRACTIONS*

Activation of Na⁺,HCO₃⁻ cotransport in vascular smooth muscle cells (VSMCs) contributes to intracellular pH (pH_i) control during artery contraction, but the signaling pathways involved have been unknown. We investigated whether physical and functional interactions between the Na⁺,HCO₃⁻ cotransporter NBCn1 (slc4a7) and the Ca²⁺/calmodulin-activated serine/threonine phosphatase calcineurin exist and play a role for pH_i control in VSMCs. Using a yeast two-hybrid screen, we found that splice cassette II from the N terminus of NBCn1 interacts with calcineurin Aβ. When cassette II was truncated or mutated to disrupt the putative calcineurin binding motif PTVVIH, the interaction was abolished. Native NBCn1 and calcineurin Aβ co-immunoprecipitated from A7r5 rat VSMCs. A peptide (acetyl-DDIPTVVIH-amide), which mimics the putative calcineurin binding motif, inhibited the co-immunoprecipitation whereas a mutated peptide (acetyl-DDIATAVAA-amide) did not. Na⁺,HCO₃⁻ cotransport activity was investigated in VSMCs of mesenteric arteries after an NH₄⁺ prepulse. During depolarization with 50 mm extracellular K⁺ to raise intracellular [Ca²⁺], Na⁺,HCO₃⁻ cotransport activity was inhibited 20–30% by calcineurin inhibitors (FK506 and cyclosporine A). FK506 did not affect Na⁺,HCO₃⁻ cotransport activity in VSMCs when cytosolic [Ca²⁺] was lowered by buffering, nor did it disrupt binding between NBCn1 and calcineurin Aβ. FK506 augmented the intracellular acidification of VSMCs during norepinephrine-induced artery contractions. No physical or functional interactions between calcineurin Aβ and the Na⁺/H⁺ exchanger NHE1 were observed in VSMCs. In conclusion, we demonstrate a physical interaction between calcineurin Aβ and cassette II of NBCn1. Intracellular Ca²⁺ activates Na⁺,HCO₃⁻ cotransport activity in VSMCs in a calcineurin-dependent manner which is important for protection against intracellular acidification.     

Na-Independent HCO(3) Transport and Accumulation in the Cyanobacterium Synechococcus UTEX 625

The active transport and intracellular accumulation of HCO₃⁻ by air-grown cells of the cyanobacterium Synechococcus UTEX 625 (PCC 6301) was strongly promoted by 25 millimolar Na⁺.Na⁺-dependent HCO₃⁻ accumulation also resulted in a characteristic enhancement in the rate of photosynthetic O₂ evolution and CO₂ fixation. However, when Synechococcus was grown in standing culture, high rates of HCO₃⁻ transport and photosynthesis were observed in the absence of added Na⁺. The internal HCO₃⁻ pool reached levels up to 50 millimolar, and an accumulation ratio as high as 970 was observed. Sodium enhanced HCO₃⁻ transport and accumulation in standing culture cells by about 25 to 30% compared with the five- to eightfold enhancement observed with air-grown cells. The ability of standing culture cells to utilize HCO₃⁻ from the medium in the absence of Na⁺ was lost within 16 hours after transfer to air-grown culture and was reacquired during subsequent growth in standing culture. Studies using a mass spectrometer indicated that standing culture cells were also capable of active CO₂ transport involving a high-affinity transport system which was reversibly inhibited by H₂S, as in the case for air-grown cells. The data are interpreted to indicate that Synechococcus possesses a constitutive CO₂ transport system, whereas Na⁺-dependent and Na⁺-independent HCO₃⁻ transport are inducible, depending upon the conditions of growth. Intracellular accumulation of HCO₃⁻ was always accompanied by a quenching of chlorophyll a fluorescence which was independent of CO₂ fixation. The extent of fluorescence quenching was highly dependent upon the size of the internal pool of HCO₃⁻ + CO₂. The pattern of fluorescence quenching observed in response to added HCO₃⁻ and Na⁺ in air-grown and standing culture cells was highly characteristic for Na⁺-dependent and Na⁺-independent HCO₃⁻ accumulation. It was concluded that measurements of fluorescence quenching provide an indirect means for following HCO₃⁻ transport and the dynamics of intracellular HCO₃⁻ accumulation and dissipation.     

Enhancement of Nitrate Uptake and Growth of Barley Seedlings by Calcium under Saline Conditions

The effect of Ca²⁺ on NO₃⁻ assimilation in young barley (Hordeum vulgare L. var CM 72) seedlings in the presence and absence of NaCl was studied. Calcium increased the activity of the NO₃⁻ transporter under saline conditions, but had little effect under nonsaline conditions. Calcium decreased the induction period for the NO₃⁻ transporter under both saline and nonsaline conditions but had little effect on its apparent K_m for NO₃⁻ both in the presence and absence of NaCl. The enhancement of NO₃⁻ transport by Ca²⁺ under saline conditions was dependent on the presence of Ca²⁺ in the uptake solution along with the salt, since Ca²⁺ had no effect when supplied before or after salinity stress. Although Mn²⁺ and Mg²⁺ enhanced NO₃⁻ uptake under saline conditions, neither was as effective as Ca²⁺. In longer studies, increasing the Ca²⁺ concentration in saline nutrient solutions resulted in increases in NO₃⁻ assimilation and seedling growth.     

Bicarbonate-Reversible and Irreversible Inhibition of Photosystem II by Monovalent Anions

We tested a number of inhibitory monovalent anions for their primary site of action on photosystem II(PSII) in chloroplasts. We find that the inhibitory effects of F⁻, HCO₂⁻, NO₂⁻, NO₃⁻, and CH₃CO₂⁻ are all reversed by addition of a high concentration of HCO₃⁻. This class of anions competitively inhibits H¹⁴CO₃⁻ binding to PSII. All of those anions tested reduced H¹⁴CO₃⁻ binding more in the light than in the dark. We conclude that the primary inhibitory site of action of a number of monovalent anions is at the HCO₃⁻ binding site(s) on the PSII complex. The carbonic anhydrase inhibitor gold cyanide, and also azide, inhibit PSII but at a site other than the HCO₃⁻ binding site. We suggest that the unique ability of HCO₃⁻ to reverse the effects of inhibitory anions reflects its singular ability to act as a proton donor/acceptor at the anion binding site. A similar role has been proposed for non-substrate-bound HCO₃⁻ on carbonic anhydrase by Yeagle et al. (1975 Proc Natl Acad Sci USA 72: 454-458).     

Influence of myosin heavy chains on the Ca2+-binding properties of light chain, LC2

The association of myosin light chains with heavy chains, i.e. the intact oligomeric structure, profoundly affects the Ca²⁺-binding properties of the light chains. The Ca²⁺-binding affinity of the light chains is more than two magnitudes higher in the presence of heavy chains than in its absence. Modification of the reactive SH₂ thiol of myosin results in an alteration in the conformation of heavy chains of the molecule that influences the Ca²⁺-binding properties of light chains and generation of tension. When the SH₂ moiety is blocked with N-ethylmaleimide the influence of the heavy chains on the Ca²⁺-binding properties of light chain LC₂ is lost; under these conditions the Ca²⁺-binding affinity value of SH₂-N-ethylmaleimide-blocked myosin (3.3×10⁴m⁻¹) decreases to near that expressed with the dissociated light chain LC₂ (0.7×10⁴m⁻¹). Conversely, the presence of actin, nucleotides or modification of either the reactive lysyl residue or SH₂ thiol does not affect Ca²⁺ binding. The native secondary and tertiary structure of myosin seem to be required for Ca²⁺ binding; binding does not occur in the presence of 6m-urea with either native myosin or the dissociated light chains. With SH₂-N-ethylmaleimide-blocked myosin normal Ca²⁺- and (Mg²⁺+actin)-stimulated ATPase activities are expressed; however, there is a loss in K⁺-stimulated ATPase activity and the synthetic actomyosin threads of such myosin express no isometric tension. There are also variances in the binding of Ca²⁺ with alterations in pH values. In the absence of Ca²⁺/EGTA buffer the biphasic Ca²⁺-binding affinity of myosin is twice as high at pH7.4 (site one: 1.2×10⁶m⁻¹ and site two: 0.4×10⁶m⁻¹) as compared with values obtained at pH6.5 (site one: 0.64×10⁶m⁻¹ and site two: 0.2×10⁶m⁻¹). The Ca²⁺-binding affinity of light chain LC₂ and S₁, where the (S-1)–(S-2) junction was absent, were not influenced by changes in pH values. Both expressed a low Ca²⁺-binding affinity, approx. 0.7×10⁴m⁻¹, whereas heavy meromyosin, where both (S-1) and (S-2) myosin subfragments were present, expressed a Ca²⁺-binding affinity value similar to that of native myosin, but was not biphasic. However, it is important to point out than in preparation of S₁ myosin subfragment light chain LC₂ was lost and thus was added back to the purified S₁ fraction. Light chain LC₂ was not, however, added to the heavy meromyosin fraction because it was not lost during preparation of the heavy meromyosin subfragment. In conclusion, it appears that the (S-1)–(S-2) junction is needed for the positioning of light chain LC₂ and thus influences its essential conformation for Ca²⁺ binding.     

Inability of tributyltin-induced chloride/hydroxyl exchange to stimulate calcium transport in mitochondria isolated from flight muscle of the sheep blowfly Lucilia cuprina

Tributyltin in the concentration range 1–4μm failed to stimulate Ca²⁺ transport by Lucilia flight-muscle mitochondria in a medium containing KCl and respiratory substrate but devoid of P_i, despite its promotion of a rapid Cl⁻/OH⁻ exchange. When 2mm-P_i was present, concentrations of tributyltin greater than 1μm inhibited the initial rate of Ca²⁺ transport and induced efflux of the ion from the mitochondria in Cl⁻- or NO₃⁻-containing media. Lower concentrations had little effect. Oligomycin added at up to 10μg/mg of mitochondrial protein had no effect on Ca²⁺ transport. By contrast, approx. 0.3μm-tributyltin completely inhibited respiration supported by α-glycerophosphate in either the presence or absence of added ADP. The data suggest that tributyltin can inhibit Ca²⁺ transport in Lucilia flight-muscle mitochondria other than by facilitating a Cl⁻/OH⁻ exchange or producing an oligomycin-like effect.     

Evidence for Na-Independent HCO(3) Uptake by the Cyanobacterium Synechococcus leopoliensis

At low levels of dissolved inorganic carbon (DIC) and alkaline pH the rate of photosynthesis by air-grown cells of Synechococcus leopoliensis (UTEX 625) was enhanced 7- to 10-fold by 20 millimolar Na⁺. The rate of photosynthesis greatly exceeded the CO₂ supply rate and indicated that HCO₃⁻ was taken up by a Na⁺-dependent mechanism. In contrast, photosynthesis by Synechococcus grown in standing culture proceeded rapidly in the absence of Na⁺ and exceeded the CO₂ supply rate by 8 to 45 times. The apparent photosynthetic affinity (K_½) for DIC was high (6-40 micromolar) and was not markedly affected by Na⁺ concentration, whereas with air-grown cells K_½ (DIC) decreased by more than an order of magnitude in the presence of Na⁺. Lithium, which inhibited Na⁺-dependent HCO₃⁻ uptake in air-grown cells, had little effect on Na⁺-independent HCO₃⁻ uptake by standing culture cells. A component of total HCO₃⁻ uptake in standing culture cells was also Na⁺-dependent with a K_½ (Na⁺) of 4.8 millimolar and was inhibited by lithium. Analysis of ¹⁴C-fixation during isotopic disequilibrium indicated that standing culture cells also possessed a Na⁺-independent CO₂ transport system. The conversion from Na⁺-independent to Na⁺-dependent HCO₃⁻ uptake was readily accomplished by transferring cells grown in standing to growth in cultures bubbled with air. These results demonstrated that the conditions experienced during growth influenced the mode by which Ssynechococcus acquired HCO₃⁻ for subsequent photosynthetic fixation.     

Essential Role of the CBD1-CBD2 Linker in Slow Dissociation of Ca2+ from the Regulatory Two-domain Tandem of NCX1

In NCX proteins CBD1 and CBD2 domains are connected through a short linker (3 or 4 amino acids) forming a regulatory tandem (CBD12). Only three of the six CBD12 Ca²⁺-binding sites contribute to NCX regulation. Two of them are located on CBD1 (K_d = ∼0.2 μm), and one is on CBD2 (K_d = ∼5 μm). Here we analyze how the intrinsic properties of individual regulatory sites are affected by linker-dependent interactions in CBD12 (AD splice variant). The three sites of CBD12 and CBD1 + CBD2 have comparable K_d values but differ dramatically in their Ca²⁺ dissociation kinetics. CBD12 exhibits multiphasic kinetics for the dissociation of three Ca²⁺ ions (k_r = 280 s⁻¹, k_f = 7 s⁻¹, and k_s = 0.4 s⁻¹), whereas the dissociation of two Ca²⁺ ions from CBD1 (k_f = 16 s⁻¹) and one Ca²⁺ ion from CBD2 (k_r = 125 s⁻¹) is monophasic. Insertion of seven alanines into the linker (CBD12–7Ala) abolishes slow dissociation of Ca²⁺, whereas the kinetic and equilibrium properties of three Ca²⁺ sites of CBD12–7Ala and CBD1 + CBD2 are similar. Therefore, the linker-dependent interactions in CBD12 decelerate the Ca²⁺ on/off kinetics at a specific CBD1 site by 50–80-fold, thereby representing Ca²⁺ “occlusion” at CBD12. Notably, the kinetic and equilibrium properties of the remaining two sites of CBD12 are “linker-independent,” so their intrinsic properties are preserved in CBD12. In conclusion, the dynamic properties of three sites are specifically modified, conserved, diversified, and integrated by the linker in CBD12, thereby generating a wide range dynamic sensor.     

Utilization of Inorganic Carbon by Ulva lactuca

Thalli discs of the marine macroalga Ulva lactuca were given inorganic carbon in the form of HCO₃⁻, and the progression of photosynthetic O₂ evolution was followed and compared with predicted O₂ evolution as based on calculated external formation of CO₂ (extracellular carbonic anhydrase was not present in this species) and its carboxylation (according to the K_m(CO₂) of ribulose-1,5-bisphosphate carboxylase/oxygenase), at two different pHs, assuming a photosynthetic quotient of 1. The K_m(inorganic carbon) was some 2.5 times lower at pH 5.6 than at the natural seawater pH of 8.2, whereas V_max was similar under the two conditions, indicating that the unnaturally low pH per se had no adverse effect on U. lactuca's photosynthetic performance. These results, therefore, could be evaluated with regard to differential CO₂ and HCO₃⁻ utilization. The photosynthetic performance observed at the lower pH largely followed that predicted, with a slight discrepancy probably reflecting a minor diffusion barrier to CO₂ uptake. At pH 8.2, however, dehydration rates were too slow to supply CO₂ for the measured photosynthetic response. Given the absence of external carbonic anhydrase activity, this finding supports the view that HCO₃⁻ transport provides higher than external concentrations of CO₂ at the ribulose-1,5-bisphosphate carboxylase/oxygenase site. Uptake of HCO₃⁻ by U. lactuca was further indicated by the effects of potential inhibitors at pH 8.2. The alleged band 3 membrane anion exchange protein inhibitor 4,4′-diisothiocyanostilbene-2,2′disulphonate reduced photosynthetic rates only when HCO₃⁻ (but not CO₂) could be the extracellular inorganic carbon form taken up. A similar, but less drastic, HCO₃⁻-competitive inhibition of photosynthesis was obtained with Kl and KNO₃. It is suggested that, under ambient conditions, HCO₃⁻ is transported into cells at defined sites either via facilitated diffusion or active uptake, and that such transport is the basis for elevated internal [CO₂] at the site of ribulose-1,5-bisphosphate carboxylase/oxygenase carboxylation.     

Na-H Exchanger Isoform-2 (NHE2) Mediates Butyrate-dependent Na+ Absorption in Dextran Sulfate Sodium (DSS)-induced Colitis

Diarrhea associated with ulcerative colitis (UC) occurs primarily as a result of reduced Na⁺ absorption. Although colonic Na⁺ absorption is mediated by both epithelial Na⁺ channels (ENaC) and Na-H exchangers (NHE), inhibition of NHE-mediated Na⁺ absorption is the primary cause of diarrhea in UC. As there are conflicting observations reported on NHE expression in human UC, the present study was initiated to identify whether NHE isoforms (NHE2 and NHE3) expression is altered and how Na⁺ absorption is regulated in DSS-induced inflammation in rat colon, a model that has been used to study UC. Western blot analyses indicate that neither NHE2 nor NHE3 expression is altered in apical membranes of inflamed colon. Na⁺ fluxes measured in vitro under voltage clamp conditions in controls demonstrate that both HCO₃⁻-dependent and butyrate-dependent Na⁺ absorption are inhibited by S3226 (NHE3-inhibitor), but not by HOE694 (NHE2-inhibitor) in normal animals. In contrast, in DSS-induced inflammation, butyrate-, but not HCO₃⁻-dependent Na⁺ absorption is present and is inhibited by HOE694, but not by S3226. These observations indicate that in normal colon NHE3 mediates both HCO₃⁻-dependent and butyrate-dependent Na⁺ absorption, whereas DSS-induced inflammation activates NHE2, which mediates butyrate-dependent (but not HCO₃⁻-dependent) Na⁺ absorption. In in vivo loop studies HCO₃⁻-Ringer and butyrate-Ringer exhibit similar rates of water absorption in normal rats, whereas in DSS-induced inflammation luminal butyrate-Ringer reversed water secretion observed with HCO₃⁻-Ringer to fluid absorption. Lumen butyrate-Ringer incubation activated NHE3-mediated Na⁺ absorption in DSS-induced colitis. These observations suggest that the butyrate activation of NHE2 would be a potential target to control UC-associated diarrhea.     

Intracellular pH Regulation in Cultured Astrocytes from Rat Hippocampus : II. Electrogenic Na/HCO3 Cotransport

In the preceding paper (Bevensee, M.O., R.A. Weed, and W.F. Boron. 1997. J. Gen. Physiol. 110: 453–465.), we showed that a Na⁺-driven influx of HCO₃ ⁻ causes the increase in intracellular pH (pH_i) observed when astrocytes cultured from rat hippocampus are exposed to 5% CO₂/17 mM HCO₃ ⁻. In the present study, we used the pH-sensitive fluorescent indicator 2′,7′-biscarboxyethyl-5,6-carboxyfluorescein (BCECF) and the perforated patch-clamp technique to determine whether this transporter is a Na⁺-driven Cl-HCO₃ exchanger, an electrogenic Na/HCO₃ cotransporter, or an electroneutral Na/HCO₃ cotransporter. To determine if the transporter is a Na⁺-driven Cl-HCO₃ exchanger, we depleted the cells of intracellular Cl⁻ by incubating them in a Cl⁻-free solution for an average of ∼11 min. We verified the depletion with the Cl⁻-sensitive dye N-(6-methoxyquinolyl)acetoethyl ester (MQAE). In Cl⁻-depleted cells, the pH_i still increases after one or more exposures to CO₂/HCO₃ ⁻. Furthermore, the pH_i decrease elicited by external Na⁺ removal does not require external Cl⁻. Therefore, the transporter cannot be a Na⁺-driven Cl-HCO₃ exchanger. To determine if the transporter is an electrogenic Na/ HCO₃ cotransporter, we measured pH_i and plasma membrane voltage (V_m) while removing external Na⁺, in the presence/absence of CO₂/HCO₃ ⁻ and in the presence/absence of 400 μM 4,4′-diisothiocyanatostilbene-2,2′-disulphonic acid (DIDS). The CO₂/HCO₃ ⁻ solutions contained 20% CO₂ and 68 mM HCO₃ ⁻, pH 7.3, to maximize the HCO₃ ⁻ flux. In pH_i experiments, removing external Na⁺ in the presence of CO₂/HCO₃ ⁻ elicited an equivalent HCO₃ ⁻ efflux of 281 μM s⁻¹. The HCO₃ ⁻ influx elicited by returning external Na⁺ was inhibited 63% by DIDS, so that the predicted DIDS-sensitive V_m change was 3.3 mV. Indeed, we found that removing external Na⁺ elicited a DIDS-sensitive depolarization that was 2.6 mV larger in the presence than in the absence of CO₂/ HCO₃ ⁻. Thus, the Na/HCO₃ cotransporter is electrogenic. Because a cotransporter with a Na⁺:HCO₃ ⁻ stoichiometry of 1:3 or higher would predict a net HCO₃ ⁻ efflux, rather than the required influx, we conclude that rat hippocampal astrocytes have an electrogenic Na/HCO₃ cotransporter with a stoichiometry of 1:2.     

Ae4 (Slc4a9) Anion Exchanger Drives Cl? Uptake-dependent Fluid Secretion by Mouse Submandibular Gland Acinar Cells

Transcellular Cl⁻ movement across acinar cells is the rate-limiting step for salivary gland fluid secretion. Basolateral Nkcc1 Na⁺-K⁺-2Cl⁻ cotransporters play a critical role in fluid secretion by promoting the intracellular accumulation of Cl⁻ above its equilibrium potential. However, salivation is only partially abolished in the absence of Nkcc1 cotransporter activity, suggesting that another Cl⁻ uptake pathway concentrates Cl⁻ ions in acinar cells. To identify alternative molecular mechanisms, we studied mice lacking Ae2 and Ae4 Cl⁻/HCO₃⁻ exchangers. We found that salivation stimulated by muscarinic and β-adrenergic receptor agonists was normal in the submandibular glands of Ae2^−/− mice. In contrast, saliva secretion was reduced by 35% in Ae4^−/− mice. The decrease in salivation was not related to loss of Na⁺-K⁺-2Cl⁻ cotransporter or Na⁺/H⁺ exchanger activity in Ae4^−/− mice but correlated with reduced Cl⁻ uptake during β-adrenergic receptor activation of cAMP signaling. Direct measurements of Cl⁻/HCO₃⁻ exchanger activity revealed that HCO₃⁻-dependent Cl⁻ uptake was reduced in the acinar cells of Ae2^−/− and Ae4^−/− mice. Moreover, Cl⁻/HCO₃⁻ exchanger activity was nearly abolished in double Ae4/Ae2 knock-out mice, suggesting that most of the Cl⁻/HCO₃⁻ exchanger activity in submandibular acinar cells depends on Ae2 and Ae4 expression. In conclusion, both Ae2 and Ae4 anion exchangers are functionally expressed in submandibular acinar cells; however, only Ae4 expression appears to be important for cAMP-dependent regulation of fluid secretion.     

Selective and Reversible Inhibition of Active CO(2) Transport by Hydrogen Sulfide in a Cyanobacterium

The active transport of CO₂ in the cyanobacterium Synechococcus UTEX 625 was inhibited by H₂S. Treatment of the cells with up to 150 micromolar H₂S + HS⁻ at pH 8.0 had little effect on Na⁺-dependent HCO₃⁻ transport or photosynthetic O₂ evolution, but CO₂ transport was inhibited by more than 90%. CO₂ transport was restored when H₂S was removed by flushing with N₂. At constant total H₂S + HS⁻ concentrations, inhibition of CO₂ transport increased as the ratio of H₂S to HS⁻ increased, suggesting a direct role for H₂S in the inhibitory process. Hydrogen sulfide does not appear to serve as a substrate for transport. In the presence of H₂S and Na⁺ -dependent HCO₃⁻ transport, the extracellular CO₂ concentration rose considerably above its equilibrium level, but was maintained far below its equilibrium level in the absence of H₂S. The inhibition of CO₂ transport, therefore, revealed an ongoing leakage from the cells of CO₂ which was derived from the intracellular dehydration of HCO₃⁻ which itself had been recently transported into the cells. Normally, leaked CO₂ is efficiently transported back into the cell by the CO₂ transport system, thus maintaining the extracellular CO₂ concentration near zero. It is suggested that CO₂ transport not only serves as a primary means of inorganic carbon acquisition for photosynthesis but also serves as a means of recovering CO₂ lost from the cell. A schematic model describing the relationship between the CO₂ and HCO₃⁻ transport systems is presented.     

Cation pretreatment effects on nitrate uptake, xylem exudate, and malate levels in wheat seedlings

Week-old wheat seedlings absorbed at least 40% NO₃⁻ from NaNO₃ when preloaded with K⁺ than when preloaded with Na⁺ or Ca²⁺. Cultures of Triticum vulgare L. cv. Arthur were grown for 5 days on 0.2 mm CaSO₄, pretreated for 48 hours with either 1 mm CaSO₄, K₂SO₄, or Na₂SO₄, and then transferred to 1 mm NaNO₃. All solutions contained 0.2 mm CaSO₄. Shoots of K⁺-preloaded plants accumulated three times more NO₃⁻ than shoots of the other two treatments. Initially, the K⁺-preloaded plants contained 10-fold more malate than either Na⁺- or Ca²⁺-preloaded seedlings. During the 48-hour treatment with NaNO₃, malate in both roots and shoots of the K⁺-preloaded seedlings decreased. Seedlings preloaded with K⁺ reduced 25% more NO₃⁻ than those preloaded with either Na⁺ or Ca²⁺. These experiments indicate that K⁺ enhanced NO₃⁻ uptake and reduction even though the absorption of K⁺ and NO₃⁻ were separated in time. Xylem exudate of K⁺-pretreated plants contained roughly equivalent concentrations of K⁺ and NO₃⁻, but exudate from Na⁺ and Ca²⁺-pretreated plants contained two to four times more NO₃⁻ than K⁺. Therefore K⁺ is not an obligatory counterion for NO₃⁻ transport in xylem.     

Is HCO3? Transport in Anabaena a Na+ Symport?

Na⁺ strongly promoted HCO₃⁻ transport in Anabaena variabilis. The effect was highly specific to this cation. Kinetic analysis indicated a progressive decrease in the K_m (HCO₃⁻) of the transport system with increasing Na⁺ concentration. V_max was also affected. We raise the possibility that the transport is a Na⁺-HCO₃⁻ symport; alternatively, that a Na⁺-H⁺ antiport (or Na⁺-OH⁺ symport) system mediates the efflux of the OH⁻ ions derived from the entering HCO₃⁻ ions, and that this antiport can rate-limit HCO₃⁻ influx.     

Substrate Control of Internal Electron Transfer in Bacterial Nitric-oxide Reductase

Nitric -oxide reductase (NOR) from Paracoccus denitrificans catalyzes the reduction of nitric oxide (NO) to nitrous oxide (N₂O) (2NO + 2H⁺ + 2e⁻ →N₂O + H₂O) by a poorly understood mechanism. NOR contains two low spin hemes c and b, one high spin heme b₃, and a non-heme iron Fe_B. Here, we have studied the reaction between fully reduced NOR and NO using the “flow-flash” technique. Fully (four-electron) reduced NOR is capable of two turnovers with NO. Initial binding of NO to reduced heme b₃ occurs with a time constant of ∼1 μs at 1.5 mm NO, in agreement with earlier studies. This reaction is [NO]-dependent, ruling out an obligatory binding of NO to Fe_B before ligation to heme b₃. Oxidation of hemes b and c occurs in a biphasic reaction with rate constants of 50 s⁻¹ and 3 s⁻¹ at 1.5 mm NO and pH 7.5. Interestingly, this oxidation is accelerated as [NO] is lowered; the rate constants are 120 s⁻¹ and 12 s⁻¹ at 75 μm NO. Protons are taken up from solution concomitantly with oxidation of the low spin hemes, leading to an acceleration at low pH. This effect is, however, counteracted by a larger degree of substrate inhibition at low pH. Our data thus show that substrate inhibition in NOR, previously observed during multiple turnovers, already occurs during a single oxidative cycle. Thus, NO must bind to its inhibitory site before electrons redistribute to the active site. The further implications of our data for the mechanism of NO reduction by NOR are discussed.     

Photosynthetic HCO(3) Utilization and OH Excretion in Aquatic Angiosperms: LIGHT-INDUCED pH CHANGES AT THE LEAF SURFACE

The utilization of HCO₃⁻ as carbon source for photosynthesis by aquatic angiosperms results in the production of 1 mole OH⁻ for each mole CO₂ assimilated. The OH⁻ ions are subsequently released to the medium. In several Potamogeton and Elodea species, the site of the HCO₃⁻ influx and OH⁻ efflux are spatially separated. Described here are light- and dark-induced pH changes at the lower and upper epidermis of the leaves of Potamogeton lucens, Elodea densa, and Elodea canadensis.     

Trigeminal Ganglion Neurons of Mice Show Intracellular Chloride Accumulation and Chloride-Dependent Amplification of Capsaicin-Induced Responses

Intracellular Cl⁻ concentrations ([Cl⁻]_i) of sensory neurons regulate signal transmission and signal amplification. In dorsal root ganglion (DRG) and olfactory sensory neurons (OSNs), Cl⁻ is accumulated by the Na⁺-K⁺-2Cl⁻ cotransporter 1 (NKCC1), resulting in a [Cl⁻]_i above electrochemical equilibrium and a depolarizing Cl⁻ efflux upon Cl⁻ channel opening. Here, we investigate the [Cl⁻]_i and function of Cl⁻ in primary sensory neurons of trigeminal ganglia (TG) of wild type (WT) and NKCC1^−/− mice using pharmacological and imaging approaches, patch-clamping, as well as behavioral testing. The [Cl⁻]_i of WT TG neurons indicated active NKCC1-dependent Cl⁻ accumulation. Gamma-aminobutyric acid (GABA)_A receptor activation induced a reduction of [Cl⁻]_i as well as Ca²⁺ transients in a corresponding fraction of TG neurons. Ca²⁺ transients were sensitive to inhibition of NKCC1 and voltage-gated Ca²⁺ channels (VGCCs). Ca²⁺ responses induced by capsaicin, a prototypical stimulus of transient receptor potential vanilloid subfamily member-1 (TRPV1) were diminished in NKCC1^−/− TG neurons, but elevated under conditions of a lowered [Cl⁻]_o suggesting a Cl⁻-dependent amplification of capsaicin-induced responses. Using next generation sequencing (NGS), we found expression of different Ca²⁺-activated Cl⁻ channels (CaCCs) in TGs of mice. Pharmacological inhibition of CaCCs reduced the amplitude of capsaicin-induced responses of TG neurons in Ca²⁺ imaging and electrophysiological recordings. In a behavioral paradigm, NKCC1^−/− mice showed less avoidance of the aversive stimulus capsaicin. In summary, our results strongly argue for a Ca²⁺-activated Cl⁻-dependent signal amplification mechanism in TG neurons that requires intracellular Cl⁻ accumulation by NKCC1 and the activation of CaCCs.     

Functional Roles of the Non-Catalytic Calcium-Binding Sites in the N-Terminal Domain of Human Peptidylarginine Deiminase 4

This study investigated the functional roles of the N-terminal Ca²⁺ ion-binding sites, in terms of enzyme catalysis and stability, of peptidylarginine deiminase 4 (PAD4). Amino acid residues located in the N-terminal Ca²⁺-binding site of PAD4 were mutated to disrupt the binding of Ca²⁺ ions. Kinetic data suggest that Asp155, Asp157 and Asp179, which directly coordinate Ca3 and Ca4, are essential for catalysis in PAD4. For D155A, D157A and D179A, the k _cat/K _m,BAEE values were 0.02, 0.63 and 0.01 s⁻¹mM⁻¹ (20.8 s⁻¹mM⁻¹ for WT), respectively. Asn153 and Asp176 are directly coordinated with Ca3 and indirectly coordinated with Ca5 via a water molecule. However, N153A displayed low enzymatic activity with a k _cat value of 0.3 s⁻¹ (13.3 s⁻¹ for wild-type), whereas D176A retained some catalytic power with a k _cat of 9.7 s⁻¹. Asp168 is the direct ligand for Ca5, and Ca5 coordination by Glu252 is mediated by two water molecules. However, mutation of these two residues to Ala did not cause a reduction in the k _cat/K _m,BAEE values, which indicates that the binding of Ca5 may not be required for PAD4 enzymatic activity. The possible conformational changes of these PAD4 mutants were examined. Thermal stability analysis of the PAD4 mutants in the absence or presence of Ca²⁺ indicated that the conformational stability of the enzyme is highly dependent on Ca²⁺ ions. In addition, the results of urea-induced denaturation for the N153, D155, D157 and D179 series mutants further suggest that the binding of Ca²⁺ ions in the N-terminal Ca²⁺-binding site stabilizes the overall conformational stability of PAD4. Therefore, our data strongly suggest that the N-terminal Ca²⁺ ions play critical roles in the full activation of the PAD4 enzyme.