Several cation transporters and volume regulation in high-K dog red blood cells

Water Homeostasis and Cell Volume Maintenance and Regulation

From early unicellular organisms that formed in salty water environments to complex organisms that live on land away from water, cells have had to protect a homeostatic internal environment favorable to the biochemical reactions necessary for life. In this chapter, we will outline what steps were necessary to conserve the water within our cells and how mechanisms have evolved to maintain and regulate our cellular and organismal volume. We will first examine whole body water homeostasis and the relationship between kidney function, regulation of blood pressure, and blood filtration in the process of producing urine. We will then discuss how the composition of the lipid-rich bilayer affects its permeability to water and salts, and how the cell uses this differential to drive physiological and biochemical cellular functions. The capacity to maintain cell volume is vital to epithelial transport, neurotransmission, cell cycle, apoptosis, and cell migration. Finally, we will wrap up the chapter by discussing in some detail specific channels, cotransporters, and exchangers that have evolved to facilitate the movement of cations and anions otherwise unable to cross the lipid-rich bilayer and that are involved in maintaining or regulating cell volume.

Aquaporin-1 expression in canine peripheral erythrocytes and its relation to cell volume

To evaluate the relationship between aquaporin-1 (AQP1) expression and the cell volume of red blood cells (RBCs), canine peripheral RBCs were separated according to specific gravity, and expression of the AQP1 protein on the membrane of RBCs was compared using anti-dog AQP1 polypeptide serum. Western blot analysis indicated that there was no significant difference in AQP1 expression between large and small cell fractions. In addition, the AQP1 expression of inherited high K/low Na RBCs which are known to be 20% larger than normal RBCs, was comparable to that of normal RBCs. These results suggest that AQP1, the major water channel in RBCs, does not determine the cell volume of peripheral canine RBCs.

Ionic mechanisms of cardiac cell swelling induced by blocking Na+/K+ pump as revealed by experiments and simulation

Although the Na(+)/K(+) pump is one of the key mechanisms responsible for maintaining cell volume, we have observed experimentally that cell volume remained almost constant during 90 min exposure of guinea pig ventricular myocytes to ouabain. Simulation of this finding using a comprehensive cardiac cell model (Kyoto model incorporating Cl(-) and water fluxes) predicted roles for the plasma membrane Ca(2+)-ATPase (PMCA) and Na(+)/Ca(2+) exchanger, in addition to low membrane permeabilities for Na(+) and Cl(-), in maintaining cell volume. PMCA might help maintain the [Ca(2+)] gradient across the membrane though compromised, and thereby promote reverse Na(+)/Ca(2+) exchange stimulated by the increased [Na(+)](i) as well as the membrane depolarization. Na(+) extrusion via Na(+)/Ca(2+) exchange delayed cell swelling during Na(+)/K(+) pump block. Supporting these model predictions, we observed ventricular cell swelling after blocking Na(+)/Ca(2+) exchange with KB-R7943 or SEA0400 in the presence of ouabain. When Cl(-) conductance via the cystic fibrosis transmembrane conductance regulator (CFTR) was activated with isoproterenol during the ouabain treatment, cells showed an initial shrinkage to 94.2 +/- 0.5%, followed by a marked swelling 52.0 +/- 4.9 min after drug application. Concomitantly with the onset of swelling, a rapid jump of membrane potential was observed. These experimental observations could be reproduced well by the model simulations. Namely, the Cl(-) efflux via CFTR accompanied by a concomitant cation efflux caused the initial volume decrease. Then, the gradual membrane depolarization induced by the Na(+)/K(+) pump block activated the window current of the L-type Ca(2+) current, which increased [Ca(2+)](i). Finally, the activation of Ca(2+)-dependent cation conductance induced the jump of membrane potential, and the rapid accumulation of intracellular Na(+) accompanied by the Cl(-) influx via CFTR, resulting in the cell swelling. The pivotal role of L-type Ca(2+) channels predicted in the simulation was demonstrated in experiments, where blocking Ca(2+) channels resulted in a much delayed cell swelling.

Comparison of K-Cl cotransport expression in high and low K dog erythrocytes

K-Cl cotransport plays a crucial role in regulatory volume decrease of erythrocytes. K-Cl cotransport activities in dog erythrocytes with an inherited high Na-K pump activity (HK) and normal erythrocytes (LK) were compared. Nitrite (NO(2)) stimulated K-Cl cotransport activity in HK cells around 14-fold at 2.4 mM, and it also increased the Km value of this cotransporter. Real-time PCR and western blot analysis revealed that K-Cl cotransporter 1 was dominant, and that the quantity of K-Cl cotransporter 1 protein was comparable between HK and LK erythrocytes. These results suggest that the difference in cotransport activity was not caused by the amount of K-Cl cotransport protein but by a difference in the regulation system, which is susceptible to oxidant.

GSH depletion, K-Cl cotransport, and regulatory volume decrease in high-K/high-GSH dog red blood cells

Thiol reagents activate K-Cl cotransport (K-Cl COT), the Cl-dependent and Na-independent ouabain-resistant K flux, in red blood cells (RBCs) of several species, upon depletion of cellular glutathione (GSH). K-Cl COT is physiologically active in high potassium (HK), high GSH (HG) dog RBCs. In this unique model, we studied whether the same inverse relationship exists between GSH levels and K-Cl COT activity found in other species. The effects of GSH depletion by three different chemical reactions [nitrite (NO(2))-mediated oxidation, diazene dicarboxylic acid bis-N,N-dimethylamide (diamide)-induced dithiol formation, and glutathione S-transferase (GST)-catalyzed conjugation of GSH with 1-chloro-2,4-dinitrobenzene (CDNB)] were tested on K-Cl COT and regulatory volume decrease (RVD). After 85% GSH depletion, all three interventions stimulated K-Cl COT half-maximally with the following order of potency: diamide > NO(2) > CDNB. Repletion of GSH reversed K-Cl COT stimulation by 50%. Cl-dependent RVD accompanied K-Cl COT activation by NO(2) and diamide. K-Cl COT activation at concentration ratios of oxidant/GSH greater than unity was irreversible, suggesting either nitrosothiolation, heterodithiol formation, or GST-mediated dinitrophenylation of protein thiols. The data support the hypothesis that an intact redox system, rather than the absolute GSH levels, protects K-Cl COT activity and cell volume regulation from thiol modification.

Molecular cloning and expression of aquaporin 1 [correction of aquapolin 1] (AQP1) in dog kidney and erythroblasts

Complementary DNA of the water channel aquaporin 1 (AQP1) was cloned from dog kidney and erythroblasts. The cDNA amplified from mRNA in dog kidney was 816 bp, the same as that in bovines, but longer by 6 bp than that in humans, mice and rats. The 235-bp fragment cDNA amplified from the mRNA in dog erythroblasts, which was differentiated from peripheral blood, was completely identical to the corresponding sequence of cDNA from the dog kidney. Thus, mature red blood cells from dog may have AQP1 in their cell membranes. The amino acid sequence in dog AQP1 was 91-94% identical to that in the other species mentioned above. Dog AQP1 has six predicted transmembrane domains, two NPA motifs, one mercury-sensitive site and four consensus phosphorylation sites, the same as the other species. However, dog and bovine AQP1 have only one N-glycosylation site, while two glycosylation sites were found in human and rodent AQP1. Xenopus oocytes injected with the mRNA of the dog AQP1 exhibited high water permeability in a hyposmotic medium. Thus, dog AQP1 performs water transport the same as in the other species.

Sodium/calcium exchange: its physiological implications

The Na+/Ca2+ exchanger, an ion transport protein, is expressed in the plasma membrane (PM) of virtually all animal cells. It extrudes Ca2+ in parallel with the PM ATP-driven Ca2+ pump. As a reversible transporter, it also mediates Ca2+ entry in parallel with various ion channels. The energy for net Ca2+ transport by the Na+/Ca2+ exchanger and its direction depend on the Na+, Ca2+, and K+ gradients across the PM, the membrane potential, and the transport stoichiometry. In most cells, three Na+ are exchanged for one Ca2+. In vertebrate photoreceptors, some neurons, and certain other cells, K+ is transported in the same direction as Ca2+, with a coupling ratio of four Na+ to one Ca2+ plus one K+. The exchanger kinetics are affected by nontransported Ca2+, Na+, protons, ATP, and diverse other modulators. Five genes that code for the exchangers have been identified in mammals: three in the Na+/Ca2+ exchanger family (NCX1, NCX2, and NCX3) and two in the Na+/Ca2+ plus K+ family (NCKX1 and NCKX2). Genes homologous to NCX1 have been identified in frog, squid, lobster, and Drosophila. In mammals, alternatively spliced variants of NCX1 have been identified; dominant expression of these variants is cell type specific, which suggests that the variations are involved in targeting and/or functional differences. In cardiac myocytes, and probably other cell types, the exchanger serves a housekeeping role by maintaining a low intracellular Ca2+ concentration; its possible role in cardiac excitation-contraction coupling is controversial. Cellular increases in Na+ concentration lead to increases in Ca2+ concentration mediated by the Na+/Ca2+ exchanger; this is important in the therapeutic action of cardiotonic steroids like digitalis. Similarly, alterations of Na+ and Ca2+ apparently modulate basolateral K+ conductance in some epithelia, signaling in some special sense organs (e.g., photoreceptors and olfactory receptors) and Ca2+-dependent secretion in neurons and in many secretory cells. The juxtaposition of PM and sarco(endo)plasmic reticulum membranes may permit the PM Na+/Ca2+ exchanger to regulate sarco(endo)plasmic reticulum Ca2+ stores and influence cellular Ca2+ signaling.

Heredity of red blood cells with high K and low glutathione (HK/LG) and high K and high glutathione (HK/HG) in a family of Japanese Shiba Dogs

Forty-two of 81 dogs from a family of Japanese Shiba dogs had red blood cells with a high K and a low Na concentration (HK). Of the HK dogs, 32 were high K and low glutathione (HK/LG) and 10 were high K and high glutathione (HK/HG). These variants were found in both males and females. The phenotype of HK was inherited in a recessive mode as reported earlier. A high incidence of HK/LG dogs was found in this family, and the phenotype was also inherited in a recessive mode. Glutamate (Glu) influx, which defines the cellular glutathione concentration, was lower in HK/LG cells than in HK/HG cells (in some cases extremely low). The fact that the red blood cells of HK/LG dogs have the two varying characteristics of a remaining Na, K-pump and low Glu transport suggests that 2 or more genes may be involved. Since an extremely low Glu influx was also found in normal low K and high Na (LK) red blood cells, the characteristic of low Glu transport also exists in LK cells. The phenotype of low Glu transport may also be inherited in a recessive mode. This family therefore had a very high incidence of homozygous recessive genes which control the phenotypes for the Na, K-pump and low Glu transport.

Na-dependent glutamate transport in high K and high glutathione (HK/HG) and high K and low glutathione (HK/LG) dog red blood cells

Na-dependent glutamate (Glu) influxes in the red blood cells of normal low K (LK), high K and high glutathione (HK/HG), and high K and low glutathione (HK/LG) dogs were compared. The ranges of the influxes in LK, HK/HG and HK/LG cells were 1.0-63, 62-174 and 1.3-26 mumol/1 cells per h, respectively. Some LK and HK/LG dogs had red blood cells with extremely low Glu influxes. In cells with extremely low Glu influxes, however, there were clear Na-dependent Glu influxes. In LK, HK/HG and HK/LG cells, the Km of Na-dependent Glu influx with respect to the medium Glu concentration were 17, 20 and 19 mM, respectively, and the half-maximal activation (K1/2) with respect to medium Na concentration was 39, 40 and 42 microM, respectively. By the addition of harmaline, a hallucinogenic alkaloid, the Vmax in LK cells was not affected and the Km was increased, while the Vmax was decreased and the Km increased in HK/HG and HK/LG cells. The Ki value with harmaline by means of Dixon plot in LK cells was 5.2 mM, against 1.8 and 1.9 mM in HK/HG and HK/LG cells, respectively. These results suggest that the difference in the Na-dependent Glu influxes between 2 HK groups was due to the varying quantity, not the quality, of the transporter.

Volume-activated cation transport in dog red cells: detection and transduction of the volume stimulus

1. Carnivore red cells lose their Na/K pump capability as they develop from erythroblasts to reticulocytes to mature cells. They defend their fluid volume by utilizing the Ca/Na exchanger as a Na extrusion pump, the energy for which is ultimately derived from active Ca transport. 2. Swelling-induced [K-Cl] cotransport and shrinkage-induced Na/H exchange are regulated in a coordinated fashion in dog red cells. Circumstantial evidence points to a regulatory protein kinase-phosphatase system. 3. Dog red cells detect changes in their fluid volume, not by virtue of membrane distortion, but by alterations in the concentrations of cytoplasmic macromolecules induced by swelling or shrinkage.

Ferret red cells: Na/Ca exchange and NaKCl cotransport

The primary pathway for K influx in ferret red cells is the Na-K-Cl cotransporter and the primary pathway for Ca influx is the Na/Ca exchanger. This makes ferret red cells favorable models for the study of these two transport systems. The evidence that Na/Ca exchange is of primary importance for steady state cell volume regulation and the Na-K-Cl cotransport has a minor role is presented. The approaches to, and results of, the determination of the stoichiometry, of the mechanism, and of the regulation by ATP and Mg, for Na/Ca exchange is contrasted with that taken for Na-K-Cl cotransport.

Activation of ion transport pathways by changes in cell volume

Swelling-activated K+ and Cl- channels, which mediate RVD, are found in most cell types. Prominent exceptions to this rule include red cells, which together with some types of epithelia, utilize electroneutral [K(+)-Cl-] cotransport for down-regulation of volume. Shrinkage-activated Na+/H+ exchange and [Na(+)-K(+)-2 Cl-] cotransport mediate RVI in many cell types, although the activation of these systems may require special conditions, such as previous RVD. Swelling-activated K+/H+ exchange and Ca2+/Na+ exchange seem to be restricted to certain species of red cells. Swelling-activated calcium channels, although not carrying sufficient ion flux to contribute to volume changes may play an important role in the activation of transport pathways. In this review of volume-activated ion transport pathways we have concentrated on regulatory phenomena. We have listed known secondary messenger pathways that modulate volume-activated transporters, although the evidence that volume signals are transduced via these systems is preliminary. We have focused on several mechanisms that might function as volume sensors. In our view, the most important candidates for this role are the structures which detect deformation or stretching of the membrane and the skeletal filaments attached to it, and the extraordinary effects that small changes in concentration of cytoplasmic macromolecules may exert on the activities of cytoplasmic and membrane enzymes (macromolecular crowding). It is noteworthy that volume-activated ion transporters are intercalated into the cellular signaling network as receptors, messengers and effectors. Stretch-activated ion channels may serve as receptors for cell volume itself. Cell swelling or shrinkage may serve a messenger function in the communication between opposing surfaces of epithelia, or in the regulation of metabolic pathways in the liver. Finally, these transporters may act as effector systems when they perform regulatory volume increase or decrease. This review discusses several examples in which relatively simple methods of examining volume regulation led to the discovery of transporters ultimately found to play key roles in the transmission of information within the cell. So, why volume? Because it's functionally important, it's relatively cheap (if you happened to have everything else, you only need some distilled water or concentrated salt solution), and since it involves many disciplines of experimental biology, it's fun to do.