pH-sensitive activation of the intracellular-pH regulation system in squid axons by ATP-gamma-S

The SLC4 family of bicarbonate (HCO₃⁻) transporters

The SLC4 family consists of 10 genes (SLC4A1-5; SLC4A7-11). All encode integral membrane proteins with very similar hydropathy plots-consistent with 10-14 transmembrane segments. Nine SLC4 members encode proteins that transport HCO3(-) (or a related species, such as CO3(2-)) across the plasma membrane. Functionally, eight of these proteins fall into two major groups: three Cl-HCO3 exchangers (AE1-3) and five Na(+)-coupled HCO3(-) transporters (NBCe1, NBCe2, NBCn1, NBCn2, NDCBE). Two of the Na(+)-coupled transporters (NBCe1, NBCe2) are electrogenic; the other three Na(+)-coupled HCO3(-) transporters and all three AEs are electroneutral. In addition, two other SLC4 members (AE4, SLC4A9 and BTR1, SLC4A11) do not yet have a firmly established function. Most, though not all, SLC4 members are functionally inhibited by 4,4'-diisothiocyanatostilbene-2,2'-disulfonate (DIDS). SLC4 proteins play important roles many modes of acid-base homeostasis: the carriage of CO2 by erythrocytes, the transport of H(+) or HCO3(-) by several epithelia, as well as the regulation of cell volume and intracellular pH.

The divergence, actions, roles, and relatives of sodium-coupled bicarbonate transporters

The mammalian Slc4 (Solute carrier 4) family of transporters is a functionally diverse group of 10 multi-spanning membrane proteins that includes three Cl-HCO3 exchangers (AE1-3), five Na(+)-coupled HCO3(-) transporters (NCBTs), and two other unusual members (AE4, BTR1). In this review, we mainly focus on the five mammalian NCBTs-NBCe1, NBCe2, NBCn1, NDCBE, and NBCn2. Each plays a specialized role in maintaining intracellular pH and, by contributing to the movement of HCO3(-) across epithelia, in maintaining whole-body pH and otherwise contributing to epithelial transport. Disruptions involving NCBT genes are linked to blindness, deafness, proximal renal tubular acidosis, mental retardation, and epilepsy. We also review AE1-3, AE4, and BTR1, addressing their relevance to the study of NCBTs. This review draws together recent advances in our understanding of the phylogenetic origins and physiological relevance of NCBTs and their progenitors. Underlying these advances is progress in such diverse disciplines as physiology, molecular biology, genetics, immunocytochemistry, proteomics, and structural biology. This review highlights the key similarities and differences between individual NCBTs and the genes that encode them and also clarifies the sometimes confusing NCBT nomenclature.

Effect of polyphenols on oxidative stress and mitochondrial dysfunction in neuronal death and brain edema in cerebral ischemia

Polyphenols are natural substances with variable phenolic structures and are elevated in vegetables, fruits, grains, bark, roots, tea, and wine. There are over 8000 polyphenolic structures identified in plants, but edible plants contain only several hundred polyphenolic structures. In addition to their well-known antioxidant effects, select polyphenols also have insulin-potentiating, anti-inflammatory, anti-carcinogenic, anti-viral, anti-ulcer, and anti-apoptotic properties. One important consequence of ischemia is neuronal death and oxidative stress plays a key role in neuronal viability. In addition, neuronal death may be initiated by the activation of mitochondria-associated cell death pathways. Another consequence of ischemia that is possibly mediated by oxidative stress and mitochondrial dysfunction is glial swelling, a component of cytotoxic brain edema. The purpose of this article is to review the current literature on the contribution of oxidative stress and mitochondrial dysfunction to neuronal death, cell swelling, and brain edema in ischemia. A review of currently known mechanisms underlying neuronal death and edema/cell swelling will be undertaken and the potential of dietary polyphenols to reduce such neural damage will be critically reviewed.

Na-coupled bicarbonate transporters of the solute carrier 4 family in the nervous system: function, localization, and relevance to neurologic function

Many cellular processes including neuronal activity are sensitive to changes in intracellular and/or extracellular pH-both of which are regulated by acid-base transporter activity. HCO(3)(-)-dependent transporters are particularly potent regulators of intracellular pH in neurons and astrocytes, and also contribute to the composition of the cerebrospinal fluid (CSF). The molecular physiology of HCO(3)(-) transporters has advanced considerably over the past ∼14 years as investigators have cloned and characterized the function and localization of many Na-Coupled Bicarbonate Transporters of the solute carrier 4 (Slc4) family (NCBTs). In this review, we provide an updated overview of the function and localization of NCBTs in the nervous system. Multiple NCBTs are expressed in neurons and astrocytes in various brain regions, as well as in epithelial cells of the choroid plexus. Characteristics of human patients with SLC4 gene mutations/deletions and results from recent studies on mice with Slc4 gene disruptions highlight the functional importance of NCBTs in neuronal activity, somatosensory function, and CSF production. Furthermore, energy-deficient states (e.g., hypoxia and ischemia) lead to altered expression and activity of NCBTs. Thus, recent studies expand our understanding of the role of NCBTs in regulating the pH and ionic composition of the nervous system that can modulate neuronal activity.

ATP dependence of Na+-driven Cl-HCO3 exchange in squid axons

Squid giant axons recover from acid loads by activating a Na(+)-driven Cl-HCO(3) exchanger. We internally dialyzed axons to an intracellular pH (pH( i )) of 6.7, halted dialysis and monitored the pH(i) recovery (increase) in the presence of ATP or other nucleotides, using cyanide to block oxidative phosphorylation. We computed the equivalent acid-extrusion rate (J(H)) from the rate of pH(i) increase and intracellular buffering power. In experimental series 1, we used dialysis to vary [ATP](i), finding that Michaelis-Menten kinetics describes J (H) vs. [ATP](i), with an apparent V(max) of 15.6 pmole cm(-2 )s(-1) and K (m) of 124 microM. In series 2, we examined ATP gamma S, AMP-PNP, AMP-PCP, AMP-CPP, GMP-PNP, ADP, ADP beta S and GDP beta S to determine if any, by themselves, could support transport. Only ATP gamma S (8 mM) supported acid extrusion; ATP gamma S also supported the HCO (3)(-) -dependent (36)Cl efflux expected of a Na(+)-driven Cl-HCO(3) exchanger. Finally, in series 3, we asked whether any nucleotide could alter J (H) in the presence of a background [ATP](i) of approximately 230 microM (control J (H) = 11.7 pmol cm(-2 )s(-1)). We found J (H) was decreased modestly by 8 mM AMP-PNP (J (H) = 8.0 pmol cm(-2 )s(-1)) but increased modestly by 1 mM ADP beta S (J (H) = 16.0 pmol cm(-2 )s(-1)). We suggest that ATP gamma S leads to stable phosphorylation of the transporter or an essential activator.

Chronic continuous hypoxia decreases the expression of SLC4A7 (NBCn1) and SLC4A10 (NCBE) in mouse brain

In the mammalian CNS, hypoxia causes a wide range of physiological effects, and these effects often depend on the stage of development. Among the effects are alterations in pH homeostasis. Na+-coupled HCO3(-) transporters can play critical roles in intracellular pH regulation and several, such as NCBE and NBCn1, are expressed abundantly in the central nervous system. In the present study, we examined the effect of chronic continuous hypoxia on the expression of two electroneutral Na-coupled HCO3(-) transporters, SLC4a7 (NBCn1) and SLC4a10 (NCBE), in mouse brain, the first such study on any acid-base transporter. We placed the mice in normobaric chambers and either maintained normoxia (21% inspired O2) or imposed continuous chronic hypoxia (11% O2) for a duration of either 14 days or 28 days, starting from ages of either postnatal age 2 days (P2) or P90. We assessed protein abundance by Western blot analysis, loading equal amounts of total protein for each condition. In most cases, hypoxia reduced NBCn1 levels by 20-50%, and NCBE levels by 15-40% in cerebral cortex, subcortex, cerebellum, and hippocampus, both after 14 and 28 days, and in both pups and adults. We hypothesize that these decreases, which are out of proportion to the expected overall decreases in brain protein levels, may especially be important for reducing energy consumption.

Sodium/calcium exchanger: influence of metabolic regulation on ion carrier interactions

The Na(+)/Ca(2+) exchanger's family of membrane transporters is widely distributed in cells and tissues of the animal kingdom and constitutes one of the most important mechanisms for extruding Ca(2+) from the cell. Two basic properties characterize them. 1) Their activity is not predicted by thermodynamic parameters of classical electrogenic countertransporters (dependence on ionic gradients and membrane potential), but is markedly regulated by transported (Na(+) and Ca(2+)) and nontransported ionic species (protons and other monovalent cations). These modulations take place at specific sites in the exchanger protein located at extra-, intra-, and transmembrane protein domains. 2) Exchange activity is also regulated by the metabolic state of the cell. The mammalian and invertebrate preparations share MgATP in that role; the squid has an additional compound, phosphoarginine. This review emphasizes the interrelationships between ionic and metabolic modulations of Na(+)/Ca(2+) exchange, focusing mainly in two preparations where most of the studies have been carried out: the mammalian heart and the squid giant axon. A surprising fact that emerges when comparing the MgATP-related pathways in these two systems is that although they are different (phosphatidylinositol bisphosphate in the cardiac and a soluble cytosolic regulatory protein in the squid), their final target effects are essentially similar: Na(+)-Ca(2+)-H(+) interactions with the exchanger. A model integrating both ionic and metabolic interactions in the regulation of the exchanger is discussed in detail as well as its relevance in cellular Ca(i)(2+) homeostasis.

The SLC4 family of HCO 3 - transporters

The SLC4 family consists of ten genes. All appear to encode integral membrane proteins with very similar hydropathy plots-consistent with the presence of 10-14 transmembrane segments. At least eight SLC4 members encode proteins that transport HCO(3)(-) (or a related species, such as CO(3)(2-)) across the plasma membrane. Functionally, these eight proteins fall into two major groups: three Cl-HCO(3) exchangers (AE1-3) and five Na(+)-coupled HCO(3)(-) transporters (NBCe1, NBCe2, NBCn1, NDCBE, NCBE). Two of the Na(+)-coupled HCO(3)(- )transporters (NBCe1, NBCe2) are electrogenic; the other three Na(+)-coupled HCO(3)(-) transporters and all three AEs are electroneutral. At least NDCBE transports Cl(-) in addition to Na(+) and HCO(3)(-). Whether NCBE transports Cl(-)-in addition to Na(+) and HCO(3)(-)-is unsettled. In addition, two other SLC4 members (AE4 and BTR1) do not yet have a firmly established function; on the basis of homology, they fall between the two major groups. A characteristic of many, though not all, SLC4 members is inhibition by 4,4'-diisothiocyanatostilbene-2,2'-disulfonate (DIDS). SLC4 gene products play important roles in the carriage of CO(2) by erythrocytes, the absorption or secretion of H(+) or HCO(3)(-) by several epithelia, as well as the regulation of cell volume and intracellular pH.

pH regulation and proton signalling by glial cells

The regulation of H+ in nervous systems is a function of several processes, including H+ buffering, intracellular H+ sequestering, CO2 diffusion, carbonic anhydrase activity and membrane transport of acid/base equivalents across the cell membrane. Glial cells participate in all these processes and therefore play a prominent role in shaping acid/base shifts in nervous systems. Apart from a homeostatic function of H(+)-regulating mechanisms, pH transients occur in all three compartments of nervous tissue, neurones, glial cells and extracellular spaces (ECS), in response to neuronal stimulation, to neurotransmitters and hormones as well as secondary to metabolic activity and ionic membrane transport. A pivotal role for H+ regulation and shaping these pH transients must be assigned to the electrogenic and reversible Na(+)-HCO3-membrane cotransport, which appears to be unique to glial cells in nervous systems. Activation of this cotransporter results in the release and uptake of base equivalents by glial cells, processes which are dependent on the glial membrane potential. Na+/H+ and Cl-/HCO3-exchange, and possibly other membrane carriers, accomplish the set of tools in both glial cells and neurones to regulate their intracellular pH. Due to the pH dependence of a great variety of processes, including ion channel gating and conductances, synaptic transmission, intercellular communication via gap junctions, metabolite exchange and neuronal excitability, rapid and local pH transients may have signalling character for the information processing in nervous tissue. The impact of H+ signalling under both physiological and pathophysiological conditions will be discussed for a variety of nervous system functions.

Role of membrane trafficking in plasma membrane solute transport

Cells can rapidly and reversibly alter solute transport rates by changing the kinetics of transport proteins resident within the plasma membrane. Most notably, this can be brought about by reversible phosphorylation of the transporter. An additional mechanism for acute regulation of plasma membrane transport rates is by the regulated exocytic insertion of transport proteins from intracellular vesicles into the plasma membrane and their subsequent regulated endocytic retrieval. Over the past few years, the number of transporters undergoing this regulated trafficking has increased dramatically, such that what was once an interesting translocation of a few transporters has now become a widespread modality for regulating plasma membrane solute permeabilities. The aim of this article is to review the models proposed for the regulated trafficking of transport proteins and what lines of evidence should be obtained to document regulated exocytic insertion and endocytic retrieval of transport proteins. We highlight four transporters, the insulin-responsive glucose transporter, the antidiuretic hormone-responsive water channel, the urinary bladder H(+)-ATPase, and the cystic fibrosis transmembrane conductance regulator Cl- channel, and discuss the various approaches taken to document their regulated trafficking. Finally, we discuss areas of uncertainty that remain to be investigated concerning the molecular mechanisms involved in regulating the trafficking of proteins.

Change of apparent stoichiometry of proximal-tubule Na(+)-HCO3- cotransport upon experimental reversal of its orientation

Electrogenic cotransport of Na+ with HCO3- has been reported in numerous tissues. It has always been shown with a net transfer of negative charge, but in some situations achieves net outward transport of both species with a stoichiometry of at least three HCO3- ions per Na+ ion (3:1), and in other situations achieves net inward transport of both species and has a stoichiometry of at most two HCO3- ions per Na+ ion (2:1). This suggests either that there may be more than one protein responsible for Na(+)-HCO3- cotransport in different tissues or that if there is a single protein, its stoichiometry may differ depending on the orientation of net transport. The present study, using conventional or double-barreled ion-selective microelectrodes to follow basolateral membrane potential and intracellular pH or Na+ activity in Necturus proximal convoluted tubule in vivo, shows that the orientation of the basolateral Na(+)-HCO3- cotransporter can be reversed upon switching from a perfusate simulating normal acid-base conditions to one that imposes peritubular isohydric hypercapnia. Moreover, accompanying the reversal of orientation is a change of apparent stoichiometry from 3:1 to 2:1. Given that the observed change of orientation and accompanying change of apparent stoichiometry occur within seconds and in the same preparation, these results suggest that a single transport protein is responsible for both types of behavior.

Chemical probes for anion transporters of mammalian cell membranes

Mammalian cell membranes harbor several types of chloride channels, chloride-cation symporters/cotransporters, and several classes of anion exchangers/antiporters. These transport systems subserve different cellular or organismic functions, depending on the nature of the cell, the spatial organization of transporters, and their functional interplay. Chemical probing has played a central role in the structural and functional delineation of the various anion transport systems. The design of specific probes or their selection from existing sources coupled with their judicious application to the most appropriate biological system had led to the identification of specific anion transporters and to the elucidation of the underlying molecular transport mechanism. In many instances, chemical probing has remained the major or exclusive analytical tool for the functional definition or identification of a given transport system, particularly for discerning among the various anion transporters which operate in highly heterogeneous cell membrane systems. This work critically reviews the present state of the chemical armamentarium available for the most common anion transporters found in mammalian cell membranes. It encompasses the description of the most useful or commonly used probes in terms of their chemical, biochemical, physiological, and pharmacological properties. The review deals primarily with what chemical probes tell about anion transporters and, most importantly, with the limitations inherent in the use of probes in transport studies.

Gating current associated with inactivated states of the squid axon gating channel

Sodium (Na) channel gating currents were measured in squid (Loligo forbesi) axons to study transitions among states occupied by the Na channel when it is inactivated. These measurements were made at high temporal resolution with a low-noise voltage clamp. The inactivation-resistant gating current, I(g,inact), could be separated into a very fast (tau = 5-25 mus) and a slower (tau = 40-200 mus) component over a wide range of test potentials (-140 mV to 80 mV) and for three different starting potentials (-70 mV, 0 mV, and 50 mV). The time constants for these components plotted against test potential lay on two bell-shaped curves; the time constants at any particular test potential did not depend on the starting potential. Both components had charge-voltage curves that saturated between -150 mV and 50 mV. A fast spike, similar to the fast component of I(g, inact), was also apparent in recordings of the fully recovered total "on" gating current. I(g, inact)(fast) and I(g, inact)(slow) could not together be described by the simplest possible model, a linear three-state scheme; however, I(g, inact)(fast) could be modeled by a two-state scheme operating in parallel with other gating processes. I(g, inact)(slow) and the gating current due to recovery from inactivated states into resting states could together be well described by a three-state scheme. This lends support to models in which a pair of inactivated states are connected by a single voltage-dependent step to the resting states of the Na system.

Regulation of intracellular pH by a neuronal homolog of the erythrocyte anion exchanger

We have isolated AE3, a novel gene expressed primarily in brain neurons and in heart. The predicted AE3 polypeptide shares a high degree of identity with the anion exchange and cytoskeletal binding domains of the erythrocyte band 3 protein. Expression of AE3 cDNA in COS cells leads to chronic cytoplasmic acidification and to chloride- and bicarbonate-dependent changes in intracellular pH, confirming that this gene product is an anion exchanger. Characterization of an AE3 mutant lacking the NH2-terminal 645 amino acids demonstrates that the COOH-terminal half of the polypeptide is both necessary and sufficient for correct insertion into the plasma membrane and for anion exchange activity. The NH2-terminal domain may play a role in regulating the activity of the exchanger and may be involved in the structural organization of the cytoskeleton in neurons.

Role of HCO3- in regulation of cytoplasmic pH in ciliary epithelial cells

Cytoplasmic pH (pHi) was monitored using the pH-sensitive absorbance of 5(6)carboxy-4',5'-dimethylfluorescein in monolayers of a cell clone derived from bovine pigmented ciliary epithelium (PE) transformed with the simian virus 40. 1) Changing extracellular media from a nominally HCO3(-)-free solution to a solution containing 28 mM HCO3(-)-5% CO2 at constant extracellular pH (7.4) resulted in a delayed alkalinization of pHi, which was 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) sensitive and was inhibited in Na+-free medium and in Cl(-)-depleted cells. 2) DIDS pretreatment acidified pHi in HCO3(-)-containing media. 3) Replacing extracellular Cl- resulted in a DIDS-sensitive, HCO3(-)-dependent, and Na+-independent alkalinization. 4) Replacing extracellular Na+ in HCO3(-)-containing media led to a partly DIDS-sensitive intracellular acidification. 5) Recovery of pHi after an alkali load (acetate prepulse) had a HCO3(-)-dependent and DIDS-sensitive component. 6) Two Na+-dependent components participated in pHi regulation after an acid load (NH4+ prepulse) in HCO3(-)-containing solution. One was amiloride sensitive, the other was DIDS sensitive and was inhibited in HCO3(-)-free media and after Cl- depletion. We conclude that in cultured PE, in addition to Na+-H+ exchange, two HCO3-transporters participate in pHi regulation. Cl(-)-dependent Na+-HCO3-symport regulates pHi during steady state and after an acid load, and Na+-independent Cl(-)-HCO3-exchange is involved in pHi recovery after an alkali load.

An ATP-dependent Na+/Mg2+ countertransport is the only mechanism for Mg extrusion in squid axons

The components of magnesium efflux in squid axons have been studied under internal dialysis and voltage clamp conditions. The present report rules out the existence of an ATP-dependent, Nao- and Mgo-independent Mg2+ efflux (ATP-dependent Mg2+ pump) leaving the Mg2+-Na+ exchange system as the only mechanism for Mg2+ extrusion. The main features of the Mg2+ efflux are: (1) The efflux is completely dependent on ATP. (2) The efflux can be activated either by external Na+ (forward Mg2+-Na+ exchange) or external Mg2+ (Mg2+-Mg2+ exchange). (3) The mobility of the Mg2+ exchanger in the Na+o-loaded form is greater than that in the Mg2+-loaded one. (4) In variance with the Na+-Ca2+ exchange mechanism, Mg2+-Mg2+ exchange is not activated by external monovalent cations. (5) ATP gamma S replaces ATP in activating Mg2+-Na+ exchange suggesting that a phosphorylation/dephosphorylation process regulates this transport mechanism.