Voltage-gated calcium channels in rat Sertoli cells.

We have studied Ca2+ voltage-gated channels of immature rat Sertoli cells by measuring intracellular Ca2+ concentration and its variation following administration of various agents in fura-2-loaded, confluent monolayers in culture. Our findings indicate that the basal Ca2+ intracellular level is about 100 nM, a value that falls within the range found in most eukaryotic cells. The intracellular Ca2+ level is rapidly increased by fetal bovine serum through release of intracellularly stored Ca2+ and opening of membrane cation channels. Substantial Ca2+ influx in rat Sertoli cells seems to be mediated by voltage-gated cation channels, which are sensitive to nifedipine, nicardipine, and omega-conotoxin. To investigate whether FSH, which controls several morphological and biochemical events of prepubertal Sertoli cells, modified Ca2+ influx in this cell type, we analyzed the cell response to acute FSH administration. The results show that, although not influencing the basal concentration of Ca2+, FSH decreases intracellular calcium influx induced by membrane depolarization. Similar data were also obtained by adding dibutyryl cAMP to the external medium and by increasing endogenous cAMP.     

Hydrophilic solute transport across rat alveolar epithelium

Diffusional fluxes of a series of hydrophilic nonelectrolytes (molecular radii ranging from 0.15 to 0.57 nm) were measured across the alveolocapillary barrier in the isolated perfused fluid-filled rat lung. Radiolabeled solutes were lavaged into the distal air spaces of isolated Ringer-perfused lungs, and apparent permeability-surface area products were calculated from the rates of isotope appearance in the recirculating perfusate. These data were used to estimate theoretical equivalent pore radii in the alveolar epithelium, with the assumption of diffusive flow through water-filled cylindrical pores. The alveolar epithelium is best characterized by two pore populations, with small pores (radius 0.5 nm) occupying 98.7% of total pore area and larger pores (radius 3.4 nm) occupying 1.3% of total pore area. Net water flow out of the alveolar space was measured by including an impermeant solute (dextran) in the lavage fluid and measuring its concentration in the alveolar space as a function of time. Under control conditions, net water flow averaged 167 nl/s. When 24 microM terbutaline was added to the perfusate, net water flow increased significantly to 350 nl/s (P less than 0.001). Terbutaline had no effect on the fluxes of either glycerol (which traverses the small pore pathway) or sucrose (which traverses the large pore pathway). These findings indicate that the intact mammalian alveolar epithelium is complex and highly resistant to the flow of solutes and water.     

Voltage-gated calcium channels in genetic diseases

Voltage-gated calcium channels (VGCCs) mediate calcium entry into excitable cells in response to membrane depolarization. During the past decade, our understanding of the gating and functions of VGCCs has been illuminated by the analysis of mutations linked to a heterogeneous group of genetic diseases called "calcium channelopathies". Calcium channelopathies include muscular, neurological, cardiac and vision syndromes. Recent data suggest that calcium channelopathies result not only from electrophysiological defects but also from altered alpha(1)/Ca(V) subunit protein processing, including folding, posttranslational modifications, quality control and trafficking abnormalities. Overall, functional analyses of VGCC mutations provide a more comprehensive view of the corresponding human disorders and offer important new insights into VGCC function. Ultimately, the understanding of these pathogenic channel mutations should lead to improved treatments of such hereditary diseases in humans.     

Potassium channels regulate tone in rat pulmonary veins

Intrapulmonary veins (PVs) contribute to pulmonary vascular resistance, but the mechanisms controlling PV tone are poorly understood. Although smooth muscle cell (SMC) K(+) channels regulate tone in most vascular beds, their role in PV tone is unknown. We show that voltage-gated (K(V)) and inward rectifier (K(ir)) K(+) channels control resting PV tone in the rat. PVs have a coaxial structure, with layers of cardiomyocytes (CMs) arrayed externally around a subendothelial layer of typical SMCs, thus forming spinchterlike structures. PVCMs have both an inward current, inhibited by low-dose Ba(2+), and an outward current, inhibited by 4-aminopyridine. In contrast, PVSMCs lack inward currents, and their outward current is inhibited by tetraethylammonium (5 mM) and 4-aminopyridine. Several K(V), K(ir), and large-conductance Ca(2+)-sensitive K(+) channels are present in PVs. Immunohistochemistry showed that K(ir) channels are present in PVCMs and PV endothelial cells but not in PVSMCs. We conclude that K(+) channels are present and functionally important in rat PVs. PVCMs form sphincters rich in K(ir) channels, which may modulate venous return both physiologically and in disease states including pulmonary edema.     

Voltage-gated potassium channels in brown fat cells

We studied the membrane currents of isolated cultured brown fat cells from neonatal rats using whole-cell and single-channel voltage-clamp recording. All brown fat cells that were recorded from had voltage-gated K currents as their predominant membrane current. No inward currents were seen in these experiments. The K currents of brown fat cells resemble the delayed rectifier currents of nerve and muscle cells. The channels were highly selective for K+, showing a 58-mV change in reversal potential for a 10-fold change in the external [K+]. Their selectivity was typical for K channels, with relative permeabilities of K+ greater than Rb+ greater than NH+4 much greater than Cs+, Na+. The K currents in brown adipocytes activated with a sigmoidal delay after depolarizations to membrane potentials positive to -50 mV. Activation was half maximal at a potential of -28 mV and did not require the presence of significant concentrations of internal calcium. Maximal voltage-activated K conductance averaged 20 nS in high external K+ solutions. The K currents inactivated slowly with sustained depolarization with time constants for the inactivation process on the order of hundreds of milliseconds to tens of seconds. The K channels had an average single-channel conductance of 9 pS and a channel density of approximately 1,000 channels/cell. The K current was blocked by tetraethylammonium or 4-aminopyridine with half maximal block occurring at concentrations of 1-2 mM for either blocker. K currents were unaffected by two blockers of Ca2+-activated K channels, charybdotoxin and apamin. Bath-applied norepinephrine did not affect the K currents or other membrane currents under our experimental conditions. These properties of the K channels indicate that they could produce an increase in the K+ permeability of the brown fat cell membrane during the depolarization that accompanies norepinephrine-stimulated thermogenesis, but that they do not contribute directly to the norepinephrine-induced depolarization.     

Volume flow across the alveolar epithelium of adult rat lung

We separated the solute and water flow across the alveolar epithelium from flow across airway epithelia of the adult rat. Small volumes (0.5-1.0 ml) of Krebs-Ringer bicarbonate (KRB) were trapped in the distal air space of the isolated vascular-perfused left lung lobes while the airways were blocked by immiscible O2-carrying fluorocarbon. Lobe weight was lost or gained in response to colloid gradients and was raised by metabolic inhibitors but did not change with only fluorocarbon in the air space or in response to modifiers of epithelial ion transport. When serum was added to the KRB-colloid perfusion, weight loss occurred in the absence of a colloid gradient (3.4 ml/min) and was Na+ dependent (inhibited by luminal Na(+)-free KRB). The change in the concentration of blue dextran in liquid sampled by micropuncture from subpleural alveoli was smaller than expected from lobe weight under basal conditions or with a colloid gradient, even though the volume marker accurately detected edema formation (weight gain) induced by metabolic inhibitors. We conclude that 1) weight changes represent volume absorption from the air spaces, 2) serum stimulates a Na+ absorptive process, and 3) by exclusion, small airways and/or other subpopulations of alveoli are the site of this absorption.     

Voltage-gated calcium channels direct neuronal migration in Caenorhabditis elegans

Calcium signaling is known to be important for regulating the guidance of migrating neurons, yet the molecular mechanisms underlying this process are not well understood. We have found that two different voltage-gated calcium channels are important for the accurate guidance of postembryonic neuronal migrations in the nematode Caenorhabditis elegans. In mutants carrying loss-of-function alleles of the calcium channel gene unc-2, the touch receptor neuron AVM and the interneuron SDQR often migrated inappropriately, leading to misplacement of their cell bodies. However, the AVM neurons in unc-2 mutant animals extended axons in a wild-type pattern, suggesting that the UNC-2 calcium channel specifically directs migration of the neuronal cell body and is not required for axonal pathfinding. In contrast, mutations in egl-19, which affect a different voltage-gated calcium channel, affected the migration of the AVM and SDQR bodies, as well as the guidance of the AVM axon. Thus, cell migration and axonal pathfinding in the AVM neurons appear to involve distinct calcium channel subtypes. Mutants defective in the unc-43/CaM kinase gene showed a defect in SDQR and AVM positioning that resembled that of unc-2 mutants; thus, CaM kinase may function as an effector of the UNC-2-mediated calcium influx in guiding cell migration.     

Role of pHi,and proton transporters in oncogene-driven neoplastic transformation

The change of a normal, healthy cell to a transformed cell is the first step in the evolutionary arc of a cancer. While the role of oncogenes in this ‘passage’ is well known, the role of ion transporters in this critical step is less known and is fundamental to our understanding the early physiological processes of carcinogenesis. Cancer cells and tissues have an aberrant regulation of hydrogen ion dynamics leading to a reversal of the normal tissue intracellular to extracellular pH gradient (ΔpH_i to ΔpH_e). When this perturbation in pH dynamics occurs during carcinogenesis is less clear. Very early studies using the introduction of different oncogene proteins into cells observed a concordance between neoplastic transformation and a cytoplasmic alkalinization occurring concomitantly with a shift towards glycolysis in the presence of oxygen, i.e. ‘Warburg metabolism’. These processes may instigate a vicious cycle that drives later progression towards fully developed cancer where the reversed pH gradient becomes ever more pronounced. This review presents our understanding of the role of pH and the NHE1 in driving transformation, in determining the first appearance of the cancer ‘hallmark’ characteristics and how the use of pharmacological approaches targeting pH/NHE1 may open up new avenues for efficient treatments even during the first steps of cancer development.     

Voltage-gated ion channels of inflowing current expressed in Xenopus oocytes after injection of rat brain mRNA

The expression of two types of voltage-gated ion channels of the inflowing current ("fast" sodium channels, sensitive to tetrodotoxin, and high-threshold calcium channels) was detected by electrophysiological methods in the membrane ofXenopus oocytes, after injection of poly(A)⁺-mRNA from the brains of 18- to 20-day-old rats. When Cd²⁺ (200 µmoles/liter) was added to the extracellular solution, the barium current through the expressed calcium channels was completely suppressed, but no sensitivity to D-600 (20 µmoles/liter) and nitrendipine (50 µmoles/liter) was exhibited. A peptide blocker of the high-threshold calcium channels of the neuron membrane, -conotoxin GVIA, in a concentration of 1 µmole/liter led to 20–40 min suppression of the barium current expressed in the oocyte. Steady-state inactivation of this current could be described by the Boltzman formula, using the values of the half-inactivation potential V_1/2=–50 mV and the steepness factor k=14 mV. It is concluded that in potential-dependent and pharmacological properties, the calcium channels expressed in the oocyte, despite the absence of any appreciable time-dependent inactivation, most resemble the high-threshold inactivatable (HTI- or N-type) calcium channels of the neuron membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 3, pp. 344–353, May–June, 1991.     

Functional expression of ERG1 potassium channels in rat alveolar macrophages

Alveolar macrophages (AMs) play a vital role in lung immunity. The recent studies demonstrated that potassium channels were associated with macrophage functions, such as activation, migration and cytokines secretion. However, less is known regarding the expression and function of ERG channels in AMs. Our study showed that ERG1 channel expressed in rat alveolar macrophage, and the expression level was increased when AMs were stimulated with LPS. Furthermore, blockade of ERG1 channels with E4031 down-regulated the mature of ERG1 protein, inhibited NF-κB translocation into the nucleus, and reduced LPS-stimulated IL-6 and IL-1β secretion. These results imply that ERG1 channels are functionally expressed in rat alveolar macrophages and play an important role in inflammatory response.     

Voltage-gated Ca2+ channels in type III taste cells

In the mammalian taste bud, the heterogeneous cell population includes three morphologically distinct types of cells, type I to type III, which are also different in their electrophysiological features. Particularly, voltage-gated (VG) Ca²⁺ channels are functional solely in taste cells of the type III. These channels were studied here with external Ba²⁺ ions as current carriers. It was specifically shown that VG Ba²⁺ currents were almost completely blockable with nifedipine as well as with ionic blockers, such as Cd²⁺, Ni²⁺, and Co²⁺. Kinetic properties of VG Ba²⁺ currents in type III cells and their sensitivity to the blockers indicated that these currents were largely mediated by VG Ca²⁺ channels of the L-type. The expression of genes, which encode pore-forming α1-subunits of Ca²⁺ channels, was analyzed using methods of molecular biology. Among four genes encoding L-type Ca²⁺ channel α1-subunits (Ca _ν 1.1-Ca _ν 1.4), the expression of Ca _ν 1.2 was demonstrated in taste cells.     

Brassinosteroids regulate plasma membrane anion channels in addition to proton pumps during expansion of Arabidopsis thaliana cells

Brassinosteroids (BRs) are involved in numerous physiological processes associated with plant development and especially with cell expansion. Here we report that two BRs, 28-homobrassinolide (HBL) and its direct precursor 28-homocastasterone (HCS), promote cell expansion of Arabidopsis thaliana suspension cells. We also show that cell expansions induced by HBL and HCS are correlated with the amplitude of the plasma membrane hyperpolarization they elicited. HBL, which promoted the larger cell expansion, also provoked the larger hyperpolarization. We observed that membrane hyperpolarization and cell expansion were partially inhibited by the proton pump inhibitor erythrosin B, suggesting that proton pumps were not the only ion transport system modulated by the two BRs. We used a voltage clamp approach in order to find the other ion transport systems involved in the PM hyperpolarization elicited by HBL and HCS. Interestingly, while anion currents were inhibited by both HBL and HCS, outward rectifying K+ currents were increased by HBL but inhibited by HCS. The different electrophysiological behavior shown by HBL and HCS indicates that small changes in the BR skeleton might be responsible for changes in bioactivity.     

GTP-binding proteins regulate high conductance anion channels in rat bile duct epithelial cells

Summary Epithelial cells from the intrahepatic bile duct contribute to bile formation, but little is known of the cellular mechanisms responsible. In these studies, we have characterized the endogenous GTP-binding proteins (G proteins) present in these cells and evaluated their role in regulation of high conductance anion channels. G proteins were identified in purified plasma membranes of isolated bile duct epithelial cells using specific antisera on Western blots, and ion channel activity was measured in excised inside-out membrane patches using patch-clamp recording techniques. In patches without spontaneous channel activity, addition of cholera toxin to the cytoplasmic surface had no effect (n=10). Addition of pertussis toxin caused an activation of channels in 13/34 (38%) attempts, as detected by an increase in channel open probability. Activated channels were anion selective (gluconate/Cl^– permeability ratio of 0.17±0.04) and had a unitary conductance of 380 pS. Channel open probability was also increased by the nonhydrolyzable GDP analogue guanosine 5-0-(2-thiodiphosphate) in 8/14 (57%) attempts. In contrast, channel open probability was rapidly and reversibly decreased by the nonhydrolyzable analogue of GTP 5guanylylimidodiphosphate in 7/9 (78%) attempts. Western blotting with specific antisera revealed that both G_i –2 and G_i –3 were present in significant amounts, whereas G_i –1 and G_o were not detected. These studies indicate that in bile duct epithelial cells, high conductance anion channels are inhibited, in a membrane-delimited manner, by PTX-sensitive G proteins.We gratefully acknowledge the assistance of Marwan Farouk, M.D. in the preparation of bile duct epithelial cells, Lucy Seger in the identification of the G proteins, C.F. Starmer in channel analysis, and P.J. Casey for the gift of bacteria expressing the different G-protein -subunits. This work was supported in part by grants from the National Institutes of Health DK43278 (to J.G.F.), DK42486 (to T.W.G.), and DK07568 (to J.M.M.); American Gastroenterological Association/G.D. Searle Research Scholar Award (to J.G.F.) and an American Gastroenterological Association Advanced Research Training Award (J.M.M.).     

Evidence for active sodium transport across alveolar epithelium of isolated rat lung

We have previously presented evidence that cultured alveolar epithelial cell monolayers actively transport sodium from medium to substratum, a process that can be inhibited by sodium transport blockers and stimulated by beta-agonists. In this study, the isolated perfused rat lung was utilized in order to investigate the presence of active sodium transport by intact adult mammalian alveolar epithelium. Radioactive tracers (22Na and [14C]sucrose) were instilled into the airways of isolated Ringer-perfused rat lungs whose weight was continuously monitored. The appearance of isotopes in the recirculated perfusate was measured, and fluxes and apparent permeability-surface area products were determined. A pharmacological agent (amiloride, ouabain, or terbutaline) was added to the perfusate during each experiment after a suitable control period. Amiloride and ouabain resulted in decreased 22Na fluxes and a faster rate of lung weight gain. Terbutaline resulted in increased 22Na flux and a more rapid rate of lung weight loss. [14C]sucrose fluxes were unchanged by the presence of these pharmacological agents. These data are most consistent with the presence of a regulable active component of sodium transport across intact mammalian alveolar epithelium that leads to removal of sodium from the alveolar space, with anions and water following passively. Regulation of the rate of sodium and fluid removal from the alveolar space may play an important role in the prevention and/or resolution of alveolar pulmonary edema.