The SLO3 sperm-specific potassium channel plays a vital role in male fertility

Here we show a unique example of male infertility conferred by a gene knockout of the sperm-specific, pH-dependent SLO3 potassium channel. In striking contrast to wild-type sperm which undergo membrane hyperpolarization during capacitation, we found that SLO3 mutant sperm undergo membrane depolarization. Several defects in SLO3 mutant sperm are evident under capacitating conditions, including impaired motility, a bent “hairpin” shape, and failure to undergo the acrosome reaction (AR). The failure of AR is rescued by valinomycin which hyperpolarizes mutant sperm. Thus SLO3 is the principal potassium channel responsible for capacitation-induced hyperpolarization, and membrane hyperpolarization is crucial to the AR.     

SLO3 K+ Channels Control Calcium Entry through CATSPER Channels in Sperm

Here we show how a sperm-specific potassium channel (SLO3) controls Ca²⁺ entry into sperm through a sperm-specific Ca²⁺ channel, CATSPER, in a totally unanticipated manner. The genetic deletion of either of those channels confers male infertility in mice. During sperm capacitation SLO3 hyperpolarizes the sperm, whereas CATSPER allows Ca²⁺ entry. These two channels may be functionally connected, but it had not been demonstrated that SLO3-dependent hyperpolarization is required for Ca²⁺ entry through CATSPER channels, nor has a functional mechanism linking the two channels been shown. In this study we show that Ca²⁺ entry through CATSPER channels is deficient in Slo3 mutant sperm lacking hyperpolarization; we also present evidence supporting the hypothesis that SLO3 channels activate CATSPER channels indirectly by promoting a rise in intracellular pH through a voltage-dependent mechanism. This mechanism may work through a Na⁺/H⁺ exchanger (sNHE) and/or a bicarbonate transporter, which utilizes the inward driving force of the Na⁺ gradient, rendering it intrinsically voltage-dependent. In addition, the sperm-specific Na⁺/H⁺ exchanger (sNHE) possess a putative voltage sensor that might be activated by membrane hyperpolarization, thus increasing the voltage sensitivity of internal alkalization.     

Iberiotoxin and clofilium regulate hyperactivation,acrosome reaction,and ion homeostasis synergistically during human sperm capacitation

Potassium channels play essential roles in the regulation of male fertility. However, potassium channels mediating K⁺ currents in human sperm (I_KSper) remain controversial. Besides SLO3, the SLO1 potassium channel is a potential candidate for human sperm KSper. This study intends to elucidate the function of SLO1 potassium channel during human sperm capacitation. Human sperm were treated with iberiotoxin (IbTX, a SLO1 specific inhibitor) and clofilium (SLO3 inhibitor) separately or simultaneously during in vitro capacitation. A computer-assisted sperm analyzer was used to assess sperm motility. The sperm acrosome reaction (AR) was analyzed using fluorescein isothiocyanate-conjugated Pisum sativum agglutinin staining. Sperm protein tyrosine phosphorylation was studied using western blotting. Intracellular Ca²⁺, K⁺, Cl⁻, and pH were analyzed using ion fluorescence probes. Independent inhibition with IbTX or clofilium decreased the sperm hyperactivation, AR, and protein tyrosine phosphorylation, and was accompanied by an increase in [K⁺]_i, [Cl⁻]_i, and pH_i, but a decrease in [Ca²⁺]_i. Simultaneously inhibition with IbTX and clofilium lower sperm hyperactivation and AR more than independent inhibition. The increase in [K⁺]_i, [Cl⁻]_i, and pH_i, and the decrease in [Ca²⁺]_i were more pronounced. This study suggested that the SLO1 potassium channel may have synergic roles with SLO3 during human sperm capacitation.     

Src Kinase Is the Connecting Player between Protein Kinase A (PKA) Activation and Hyperpolarization through SLO3 Potassium Channel Regulation in Mouse Sperm

Plasma membrane hyperpolarization is crucial for mammalian sperm to acquire acrosomal responsiveness during capacitation. Among the signaling events leading to mammalian sperm capacitation, the immediate activation of protein kinase A plays a pivotal role, promoting the subsequent stimulation of protein tyrosine phosphorylation that associates with fertilizing capacity. We have shown previously that mice deficient in the tyrosine kinase cSrc are infertile and exhibit improper cauda epididymis development. It is therefore not clear whether lack of sperm functionality is due to problems in epididymal maturation or to the absence of cSrc in sperm. To further address this problem, we investigated the kinetics of cSrc activation using anti-Tyr(P)-416-cSrc antibodies that only recognize active cSrc. Our results provide evidence that cSrc is activated downstream of PKA and that inhibition of its activity blocks the capacitation-induced hyperpolarization of the sperm plasma membrane without blocking the increase in tyrosine phosphorylation that accompanies capacitation. In addition, we show that cSrc inhibition also blocks the agonist-induced acrosome reaction and that this inhibition is overcome by pharmacological hyperpolarization. Considering that capacitation-induced hyperpolarization is mediated by SLO3, we evaluated the action of cSrc inhibitors on the heterologously expressed SLO3 channel. Our results indicate that, similar to SLO1 K⁺ channels, cSrc blockers significantly decreased SLO3-mediated currents. Together, these results are consistent with findings showing that hyperpolarization of the sperm plasma membrane is necessary and sufficient to prepare the sperm for the acrosome reaction and suggest that changes in sperm membrane potential are mediated by cSrc activation.     

Change in membrane potential induced by streptolysin O,a pore-forming toxin: flow cytometric analysis using a voltage-sensitive fluorescent probe and rat thymic lymphocytes

Streptolysin O (SLO) is a bacterial pore-forming toxin that is employed to permeabilize cell membranes in some biological experiments. SLO forms various types of pores with different shapes, increasing membrane ion permeability and subsequently inducing changes in membrane potential. To characterize the pores formed by SLO, the changes in membrane potential induced by SLO in rat lymphocytes were considered using flow cytometry with a voltage-sensitive fluorescent probe, bis-(1,3-dibutylbarbituric acid)trimethine oxonol (Oxonol). SLO caused three types of membrane potential responses accessed with Oxonol. One type induces a great decrease in Oxonol fluorescence (large hyperpolarization) that may be elicited via the increase of Ca²⁺-dependent K⁺ permeability by SLO-induced influx of external Ca²⁺. A second type is an increase in Oxonol fluorescence (depolarization) that may be caused by a nonspecific increase in membrane cation permeability. The third type is a small decrease in Oxonol fluorescence (small hyperpolarization), probably via an increase in Cl^– permeability. That SLO transitionally changes membrane ion permeability may have implications in the pathology of pyogenic group streptococci infections in which SLO is thought to be one of the key virulence factors.     

Mouse Sperm Membrane Potential Hyperpolarization Is Necessary and Sufficient to Prepare Sperm for the Acrosome Reaction

Mammalian sperm are unable to fertilize the egg immediately after ejaculation; they acquire this capacity during migration in the female reproductive tract. This maturational process is called capacitation and in mouse sperm it involves a plasma membrane reorganization, extensive changes in the state of protein phosphorylation, increases in intracellular pH (pH_i) and Ca²⁺ ([Ca²⁺]_i), and the appearance of hyperactivated motility. In addition, mouse sperm capacitation is associated with the hyperpolarization of the cell membrane potential. However, the functional role of this process is not known. In this work, to dissect the role of this membrane potential change, hyperpolarization was induced in noncapacitated sperm using either the ENaC inhibitor amiloride, the CFTR agonist genistein or the K⁺ ionophore valinomycin. In this experimental setting, other capacitation-associated processes such as activation of a cAMP-dependent pathway and the consequent increase in protein tyrosine phosphorylation were not observed. However, hyperpolarization was sufficient to prepare sperm for the acrosome reaction induced either by depolarization with high K⁺ or by addition of solubilized zona pellucida (sZP). Moreover, K⁺ and sZP were also able to increase [Ca²⁺]_i in non-capacitated sperm treated with these hyperpolarizing agents but not in untreated cells. On the other hand, in conditions that support capacitation-associated processes blocking hyperpolarization by adding valinomycin and increasing K⁺ concentrations inhibited the agonist-induced acrosome reaction as well as the increase in [Ca²⁺]_i. Altogether, these results suggest that sperm hyperpolarization by itself is key to enabling mice sperm to undergo the acrosome reaction.     

The Ionic Permeability Changes during Acetylcholine-Induced Responses of Aplysia Ganglion Cells

ACh-induced depolarization (D response) in D cells markedly decreases as the external Na⁺ is reduced. However, when Na⁺ is completely replaced with Mg⁺⁺, the D response remains unchanged. When Na⁺ is replaced with Tris(hydroxymethyl)aminomethane, the D response completely disappears, except for a slight decrease in membrane resistance. ACh-induced hyperpolarization (H response) in H cells is markedly depressed as the external Cl^- is reduced. Frequently, the reversal of the H response; i.e., depolarization, is observed during perfusion with Cl^--free media. In cells which show both D and H responses superimposed, it was possible to separate these responses from each other by perfusing the cells with either Na⁺-free or Cl^--free Ringer's solution. High [K⁺]₀ often caused a marked hyperpolarization in either D or H cells. This is due to the primary effect of high [K⁺]₀ on the presynaptic inhibitory fibers. The removal of this inhibitory afferent interference by applying Nembutal readily disclosed the predicted K⁺ depolarization. In perfusates containing normal [Na⁺]₀, the effects of Ca⁺⁺ and Mg⁺⁺ on the activities of postsynaptic membrane were minimal, supporting the current theory that the effects of these ions on the synaptic transmission are mainly presynaptic. The possible mechanism of the hyperpolarization produced by simultaneous perfusion with both high [K⁺]₀ and ACh in certain H cells is explained quantitatively under the assumption that ACh induces exclusively an increase in Cl^- permeability of the H membrane.     

THE IMPORTANCE OF HYDROLYTIC ENZYMES TO AN EXOCYTOTIC EVENT, THE MAMMALIAN SPERM ACROSOME REACTION

The mammalian sperm acrosome reaction is a unique form of exocytosis, which includes the loss of the involved membranes. Other laboratories have suggested the involvement of hydrolytic enzymes in somatic cell exocytosis and membrane fusion, and in the invertebrate sperm acrosome reaction, but there is no general agreement on such an involvement. Although reference was made to such work in this review, the focus of the review was on the evidence (summarized below) that supports or fails to support the importance of certain hydrolytic enzymes to the mammalian sperm acrosome reaction. Because the events of capacitation, the prerequisite for the mammalian acrosome reaction, and of the acrosome reaction itself are not fully understood or identified, it is not yet always possible to determine whether the role of a particular enzyme is in a very late step of capacitation or part of the acrosome reaction. (1) The results of studies utilizing inhibitors of trypsin-like enzymes suggest that such an enzyme has a role in the membrane events of the golden hamster sperm acrosome reaction. The enzyme involved may be acrosin, but it is possible that some as yet unidentified trypsin-like enzyme on the sperm surface may play a role in addition to or instead of acrosin. Results obtained by others with guinea pig, ram and mouse spermatozoa suggest that a trypsin-like enzyme is not involved in the membrane events of the acrosome reaction, but only in the loss of acrosomal matrix. Such results, which conflict with those of the hamster study, may have been due to species differences or the presence of fusion-promoting phospholipase-A or lipids contaminating the incubation media components, and in one case to the possibly damaging effects of the high level of calcium ionophore used. The role of the trypsin-like enzyme in the membrane events of the hamster sperm acrosome reaction may be to activate a putative prophospholipase and/or to hydrolyse an outer acrosomal or plasma membrane protein, thus promoting fusion. A possible role of the enzyme in the vesiculation step rather than the fusion step of the acrosome reaction cannot be ruled out at present. (2) Experiments utilizing inhibitors of phospholipase-A₂, as well as the fusogenic lysophospholipid and cis-unsaturated fatty acid hydrolysis products that would result from such enzyme activity, suggests that a sperm phospholipase-A₂ is involved in the golden hamster sperm acrosome reaction. Inhibitor and LPC addition studies in guinea pig spermatozoa have led others to the same conclusion. The fact that partially purified serum albumin is important in so many capacitation media may be explained by its contamination with phospholipase-A and/or phospholipids. Serum albumin may also play a role, at least in part, by its removal of inhibitory products released by the action of phospholipase-A₂ in the membrane. The demonstration of phospholipase-A₂ activity associated with the acrosome reaction vesicles and/or the soluble component of the acrosome of hamster spermatozoa, and the fact that exogenous phospholipase A₂ can stimulate acrosome reactions in hamster and guinea pig spermatozoa, also support a role for the sperm enzyme. The actual site or the sites of the enzyme in the sperm head are not yet known. The enzyme may be on the plasma membrane as well as, or instead of, in the acrosomal membranes or matrix. A substrate for the phospholipase may be phosphatidylcholine produced by phospholipid methylation. It is possible that more than one type of ‘fusogen’ is released by phospholipase activity (LPC and/or cis-unsaturated fatty acids, which have different roles in membrane fusion and/or vesiculation. In addition to acting as a potential ‘fusogen’, arachidonic acid released by sperm phospholipase-A₂ probably serves as precursor for cyclo-oxygenase or lipoxygenase pathway metabolites, such as prostaglandins and HETES, which might also play a role in the acrosome reaction. Although much evidence points to a role for phospholipase-A₂, phospholipase-C found in spermatozoa could also have a role in the acrosome reaction, perhaps by stimulating events leading to calcium gating, as suggested for this enzyme in somatic secretory cells. (3) A Mg²⁺-ATPase H⁺-pump is present in the acrosome of the golden hamster spermatozoon. Inhibition of this pump by certain inhibitors of ATPases (but not by those that only inhibit mitochondrial function) leads to an acrosome reaction only in capacitated spermatozoa and only in the presence of external K⁺. The enzyme is also inhibited by low levels of calcium, and such inhibition, combined with increased outer membrane permeability to H⁺ and K⁺, and possibly plasma membrane permeability to H⁺ (perhaps by the formation of channels), may be part of capacitation and/or the acrosome reaction. The pH of the hamster sperm acrosome has been shown to become more alkaline during capacitation, and such a change may result in the activation of hydrolytic enzymes in the acrosome or perhaps in a change in membrane permeability to Ca²⁺. A similar Mg²⁺-ATPase has not been found in isolated boar sperm head membranes. However, that conflicting result could have been due to the use of noncapacitated boar spermatozoa for the preparation of the membranes or to protease modification of the boar sperm enzyme during assay. (4) Inhibition of Na⁺, K⁺-ATPase inhibits the acrosome reaction of golden hamster spermatozoa, and the activity of this enzyme increases relatively early during capacitation. A late influx of K⁺ is important for the acrosome reaction. However, this late influx may not be due to Na⁺, K⁺-ATPase, but instead may be due to a K⁺ permeability increase (possibly via newly formed channels) in the membranes during capacitation. It is suggested in this review that Na⁺, K⁺-ATPase has a role early in capacitation rather than directly in the acrosome reaction (although such a role cannot yet be completely ruled out). One possible role for the enzyme in capacitation might be to stimulate glycolysis (which appears to be essential for capacitation and/or the acrosome reaction of hamster and mouse spermatozoa). The function of the influx of K⁺ just before the acrosome reaction is probably to stimulate, directly or indirectly, the H⁺-efflux required for the increase in intraacrosomal pH occurring during capacitation. Direct stimulation of the acrosome reaction by a change in membrane potential resulting directly from K⁺-influx is not a likely explanation for the hamster results. However, the importance of an earlier membrane potential change, due to increased Na⁺, K⁺-ATPase during capacitation, and/or of later membrane potential changes resulting from the pH change, cannot be ruled out. Although K⁺ is required for the hamster acrosome reaction, other workers have reported that K+ inhibits guinea pig sperm capacitation. However, the experimental procedures used in the guinea pig sperm studies raise some questions about the interpretation of those inhibition results. (5) Ca²⁺-influx is known to be required for the acrosome reaction. Others have suggested that increased Ca²⁺-influx due to inhibition or stimulation of sperm membrane calcium transport ATPases are involved in the acrosome reaction. There is as yet no direct or indirect biochemical evidence that inhibition or stimulation of such enzymatic activity is involved in the acrosome reaction, and further studies are needed on those questions. (6) I suggest that the hydrolytic enzymes important to the hamster sperm acrosome reaction will also prove important for the acrosome reaction of all other eutherian mammals.     

Interaction of the B subunit of cholera toxin with endogenous ganglioside GM1 causes changes in membrane potential of rat thymocytes

Summary The fluorescent anionic dye, bisoxonol, and flow cytometry have been used to monitor changes in the membrane potential of rat thymocytes exposed to the B subunit of cholera toxin. The B subunit induced a rapid hyperpolarization, which was due to activation of a Ca²⁺-sensitive K⁺ channel. Reduction of extracellular Ca²⁺ to <1 m by the addition of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid immediately abolished the hyperpolarization caused by the B subunit. Cells treated with quinine and tetraethylammonium lost their ability to respond to the B subunit, whereas 4-aminopyridine did not have any effect. Thus, calcium-sensitive and not voltage-gated K⁺ channels appeared to be responsible for the hyperpolarization. The results of ion substitution experiments indicated that extracellular Na⁺ was not essential for changes in membrane potential. Further studies with ouabain, amiloride and furosemide demonstrated that electrogenic Na⁺/K⁺ ATPase, Na⁺/H⁺ antiporter and Na⁺/K⁺/Cl^– cotransporter, respectively, were not involved in the hyperpolarization process induced by the B subunit. Thus, crosslinking of several molecules of ganglioside GM1 on the cell surface of rat thymocytes by the pentavalent B subunit of cholera toxin modulated plasma membrane permeability to K⁺ by triggering the opening of Ca²⁺-sensitive K⁺ channels. A role for gangliosides in regulating ion permeability would have important implications for the function of gangliosides in various cellular phenomena.     

Electrophysiological evidence for the presence of cystic fibrosis transmembrane conductance regulator (CFTR) in mouse sperm

Mammalian sperm must undergo a maturational process, named capacitation, in the female reproductive tract to fertilize the egg. Sperm capacitation is regulated by a cAMP/protein kinase A (PKA) pathway and involves increases in intracellular Ca²⁺, pH, Cl^?, protein tyrosine phosphorylation, and in mouse and some other mammals a membrane potential hyperpolarization. The cystic fibrosis transmembrane conductance regulator (CFTR), a Cl^? channel modulated by cAMP/PKA and ATP, was detected in mammalian sperm and proposed to modulate capacitation. Our whole‐cell patch‐clamp recordings from testicular mouse sperm now reveal a Cl^? selective component to membrane current that is ATP‐dependent, stimulated by cAMP, cGMP, and genistein (a CFTR agonist, at low concentrations), and inhibited by DPC and CFTR_inh‐172, two well‐known CFTR antagonists. Furthermore, the Cl^? current component activated by cAMP and inhibited by CFTR_inh‐172 is absent in recordings on testicular sperm from mice possessing the CFTR ΔF508 loss‐of‐function mutation, indicating that CFTR is responsible for this component. A Cl^? selective like current component displaying CFTR characteristics was also found in wild type epididymal sperm bearing the cytoplasmatic droplet. Capacitated sperm treated with CFTR_inh‐172 undergo a shape change, suggesting that CFTR is involved in cell volume regulation. These findings indicate that functional CFTR channels are present in mouse sperm and their biophysical properties are consistent with their proposed participation in capacitation. J. Cell. Physiol. 228: 590–601, 2013. © 2012 Wiley Periodicals, Inc.     

Calculations of K+, Na+, and Cl? fluxes across cell membrane with Na+/K+ pump, NKCC, NC cotransport and ionic channels with non-Goldman rectification in K+-channels: Normal and apoptotic cells

The balance of K⁺, Na⁺, and Cl⁻ fluxes across the cell membrane with the Na⁺/K⁺ pump, ion channels, and Na⁺K⁺2Cl⁻ (NKCC) and Na⁺-Cl⁻ (NC) cotransport was calculated to determine the mechanism of cell shrinkage in apoptosis. It is shown that all unidirectional K⁺, Na⁺, and Cl⁻ fluxes; the ion channel permeability; and the membrane potential can be found using the principle of the flux balance if the following experimental data are known: K⁺, Na⁺, and Cl⁻ concentrations in cell water; total Cl⁻ flux; total K⁺ influx; and the ouabain-inhibited pump component of the Rb⁺(K⁺) influx. The change in different ionic pathways during apoptosis was estimated by calculations based on the data reported in the preceded paper (Yurinskaya et al., 2010). It is found that cell shrinkage and the shift in ion balance in U937 cells induced to apoptosis with 1 μM staurosporine occur due to the coupling of reduced pump activity with a decrease in the integral permeability of Na⁺ channels, whereas K⁺ and Cl⁻ channel permeability remains almost unchanged. Calculations show that only a small part of the total fluxes of K⁺, Na⁺, and Cl⁻ account for the fluxes mediated by NKCC and NC cotransporters. Despite the importance of cotransport fluxes for maintaining the nonequilibrium steady-state distribution of Cl⁻, they cannot play a significant role in apoptotic cell shrinkage because of their minority and cannot be revealed by inhibitors.     

Simultaneous knockout of Slo3 and CatSper1 abolishes all alkalization- and voltage-activated current in mouse spermatozoa

During passage through the female reproductive tract, mammalian sperm undergo a maturation process termed capacitation that renders sperm competent to produce fertilization. Capacitation involves a sequence of changes in biochemical and electrical properties, the onset of a hyperactivated swimming behavior, and development of the ability to undergo successful fusion and penetration with an egg. In mouse sperm, the development of hyperactivated motility is dependent on cytosolic alkalization that then results in an increase in cytosolic Ca²⁺. The elevation of Ca²⁺ is thought to be primarily driven by the concerted interplay of two alkalization-activated currents, a K⁺ current (KSPER) composed of pore-forming subunits encoded by the Kcnu1 gene (also termed Slo3) and a Ca²⁺ current arising from a family of CATSPER subunits. After deletion of any of four CATSPER subunit genes (CATSPER1–4), the major remaining current in mouse sperm is alkalization-activated KSPER current. After genetic deletion of the Slo3 gene, KSPER current is abolished, but there remains a small voltage-activated K⁺ current hypothesized to reflect monovalent flux through CATSPER. Here, we address two questions. First, does the residual outward K⁺ current present in the Slo3 ^−/− sperm arise from CATSPER? Second, can any additional membrane K⁺ currents be detected in mouse sperm by patch-clamp methods other than CATSPER and KSPER? Here, using mice bred to lack both SLO3 and CATSPER1 subunits, we show conclusively that the voltage-activated outward current present in Slo3 ^−/− sperm is abolished when CATSPER is also deleted. Any leak currents that may play a role in setting the resting membrane potential in noncapacitated sperm are likely smaller than the pipette leak current and thus cannot be resolved within the limitation of the patch-clamp technique. Together, KSPER and CATSPER appear to be the sole ion channels present in mouse sperm that regulate membrane potential and Ca²⁺ influx in response to alkalization.     

Bioelectrical response of the Nitella flexilis cell to illumination: A new possible state of plasmalemma in a plant cell

Transient hyperpolarization of the external cytoplasmatic membrane may be observed on rapid illumination of the Nitella flexilis cell. Several important properties of that response make the latter similar to a considerable degree to the excitation response.The condition for transient hyperpolarization is the normal functioning of the electron transport chain conjugated with non-cyclic photophosphorylation.The value of the membrane potential at the moment of hyperpolarization of the external cytoplasmic membrane, is determined by the difference in the electrochemical potential of HCO₃^? or H⁺. This state of the plasmalemma supplements the two other known states: normal and depolarized (excited), when the main ions determining membrane potential are K⁺ and Cl^?.     

A mutant of Paramecium with increased relative resting potassium permeability

Fast-2, a membrane mutant of Paramecium aurelia, is due to a single-gene mutation and has behavioral abnormalities. Intracellular recordings through changes of external solutions were made. The mutant membrane hyperpolarized when it encountered solutions with low K⁺ concentration. This hyperpolarization and other associated activities were best observed in Ca- or Na-solutions devoid of K⁺. Membrane potential was plotted against the concentration of K⁺ (0.5 to 16 mM) in solutions of fixed Na⁺ or Ca⁺⁺ concentration. The slopes of the curves for the mutant membrane were steeper than those for the wild type at the lower concentrations of K⁺. Inclusion of 2 mM tetraethylammonium chloride (TEA-Cl) counteracted the mutational effects. Spontaneous action potentials in Ba-solution and the electrically evoked action potentials in various solutions are normal in this mutant. We conclude that the resting permeability to K⁺ relative to the permeabilities to Na⁺ and Ca⁺⁺ has been increased by the mutation.     

Purinergic signalling in rat GFSHR-17 granulosa cells: an <Emphasis Type="Italic">in vitro</Emphasis> model of granulosa cells in maturing follicles

Purinergic signalling in rat GFSHR-17 granulosa cells was characterised by Ca²⁺-imaging and perforated patch-clamp. We observed a resting intracellular Ca²⁺-concentration ([Ca²⁺]_i) of 100 nM and a membrane potential of −40 mV. This was consistent with high K⁺− and Cl⁻ permeability and a high intracellular Cl⁻ concentration of 40 mM. Application of ATP for 5–15 s every 3 min induced repeated [Ca²⁺]_i increases and a 30 mV hyperpolarization. The phospholipase C inhibitor U73122 or the IP₃-receptor antagonist 2-aminoethoethyl diphenyl borate suppressed ATP responses. Further biochemical and pharmacological experiments revealed that ATP responses were related to stimulation of P2Y₂ and P2Y₄ receptors and that the [Ca²⁺]_i increase was a prerequisite for hyperpolarization. Inhibitors of Ca²⁺-activated channels or K⁺ channels did not affect the ATP-evoked responses. Conversely, inhibitors of Cl⁻ channels hyperpolarized cells to −70 mV and suppressed further ATP-evoked hyperpolarization. We propose that P2Y₂ and P2Y₄ receptors in granulosa cells modulate Cl⁻ permeability by regulating Ca²⁺-release.     

Sodium Blocking Induced by a Point Mutation at the C-Terminal End of the Pore Helix of the KAT1 Channel

A plant hyperpolarization-activating K⁺ channel, KAT1, is highly selective for K⁺ over Na⁺ and is little affected by external Na⁺, which is crucial to take up K⁺ effectively in a Na⁺-containing environment. It has been shown that a mutation at the location (Thr256) preceding the selectivity signature sequence dramatically enhanced the sensitivity of the KAT1 channel to external Na⁺. We report here electrophysiological experiments for the mechanism of action of external Na⁺ on KAT1 channels. The Thr256 residue was substituted with either glutamine (Q) or glutamate (E). The wild-type channel was insensitive to external Na⁺. However, the activity of both mutant channels was significantly depressed by Na⁺ with apparent dissociation constants of 6.7 mm and 11.3 mm for T256Q and T256E, respectively. The instantaneous current-voltage relationships revealed distinct blocking mechanisms for these mutants. For T256Q a typical voltage-dependent fast blocking was shown. On the other hand, the blocking for the T256E mutant was voltage-independent at low Na⁺ concentrations and became voltage-dependent at higher concentrations. At extreme hyperpolarization the blocking was relieved significantly. These data strongly suggest that the mutation at the end of the pore helix rearranged the selectivity filter and allows Na⁺ to penetrate into the pore. Received: 16 October 2000/Revised: 20 February 2001     

Increased Resistance to Extracellular Cation Block by Mutation of the Pore Domain of the Arabidopsis Inward-rectifying K+ Channel KAT1

Inward-rectifying potassium channels in plant cells provide important mechanisms for low-affinity K⁺ uptake and membrane potential control in specific cell types, including guard cells, pulvinus cells, aleurone cells and root hair cells. K⁺ channel blockers are potent tools for studying the physiological functions and structural properties of K⁺ channels. In the present study the structural and biophysical mechanisms of Cs⁺ and TEA⁺ block of a cloned Arabidopsis inward-rectifying K⁺ channel (KAT1) were analyzed. Effects of the channel blockers Cs⁺ and TEA⁺ were characterized both extracellularly and intracellularly. Both external Cs⁺ and TEA⁺ block KAT1 currents. A mutant of KAT1 (``m2KAT1'; H267T, E269V) was produced by site-directed mutagenesis of two amino acid residues in the C-terminal portion of the putative pore (P) domain. This mutant channel was blocked less by external Cs⁺ and TEA⁺ than the wild-type K⁺ channel. Internal TEA⁺ and Cs⁺ did not significantly block either m2KAT1 or KAT1 channels. Other properties, such as cation selectivity, voltage-dependence and proton activation did not show large changes between m2KAT1 and KAT1, demonstrating the specificity of the introduced mutations. These data suggest that the amino acid positions mutated in the inward-rectifying K⁺ channel, KAT1, are accessible to external blockers and may be located on the external side of the membrane, as has been suggested for outward-rectifying K⁺ channels. Received: 31 July 1995/Revised: 5 January 1996     

Na+/K+ATPase regulates sperm capacitation through a mechanism involving kinases and redistribution of its testis‐specific isoform

Incubation of bovine sperm with ouabain, an endogenous cardiac glycoside that inhibits both the ubiquitous (ATP1A1) and testis‐specific α4 (ATP1A4) isoforms of Na⁺/K⁺ATPase, induces tyrosine phosphorylation and capacitation. The objectives of this study were to investigate: (1) fertilizing ability of bovine sperm capacitated by incubating with ouabain; (2) involvement of ATP1A4 in this process; and (3) signaling mechanisms involved in the regulation of sperm capacitation induced by inhibition of Na⁺/K⁺ATPase activity. Fresh sperm capacitated by incubating with ouabain (inhibits both ATP1A1 and ATP1A4) or with anti‐ATP1A4 immunoserum fertilized bovine oocytes in vitro. Capacitation was associated with relocalization of ATP1A4 from the entire sperm head to the post‐acrosomal region. To investigate signaling mechanisms involved in oubain‐induced regulation of sperm capacitation, sperm preparations were pre‐incubated with inhibitors of specific signaling molecules, followed by incubation with ouabain. The phosphotyrosine content of sperm preparations was determined by immunoblotting, and capacitation status of these sperm preparations were evaluated through an acrosome reaction assay. We inferred that Na⁺/K⁺ATPase was involved in the regulation of tyrosine phosphorylation in sperm proteins through receptor tyrosine kinase, nonreceptor type protein kinase, and protein kinases A and C. In conclusion, inhibition of Na⁺/K⁺ATPase induced tyrosine phosphorylation and capacitation through multiple signal transduction pathways, imparting fertilizing ability in bovine sperm. To our knowledge, this is the first report documenting both the involvement of ATP1A4 in the regulation of bovine sperm capacitation and that fresh bovine sperm capacitated by the inhibition of Na⁺/K⁺ATPase can fertilize oocytes in vitro. Mol. Reprod. Dev. 77: 136–148, 2010. © 2009 Wiley‐Liss, Inc.     

Ionic mechanisms of nonlinearity of the retinal horizontal cell membrane

Changes in ionic conductance lying at the basis of nonlinearity of the current-voltage characteristic curve of the cell (nonsynaptic) membrane of horizontal cells were studied in experiments on the goldfish and turtle retina. All measurements were made during blocking of synaptic transmission by bright light or Co⁺⁺. An increase in the K⁺ concentration led to depolarization and to a reduction of the steepness of the hyperpolarization branch of the current-voltage curve, whereas a decrease in K⁺ had the opposite effect. Changes in the Cl^– or Na⁺ concentrations had no significant effect on membrane potential or on the shape of the current-voltage curve. The principal potential-forming ion in the horizontal cells is thus K⁺; conductance for Cl^– is absent or very low, and conductance for Na⁺ also is evidently small. In the presence of Ba⁺⁺ (2–5 mM) the steepness of the hyperpolarization branch of the current-voltage curve was increased and the whole curve became more linear. It is concluded that nonlinearity of the current-voltage curve of the horizontal cell membrane is due mainly to potential-dependent potassium channels, whose conductance increases during hyperpolarization; this increase in conductance is blocked by Ba⁺⁺. An increase in the Ca⁺⁺ concentration to 20 mM led to an increase in steepness of the depolarization branch of the current-voltage curve, suggesting that depolarization increases membrane conductance for Ca⁺⁺.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 531–539, September–October, 1981.     

The Sodium-Potassium Exchange Pump: II. Analysis of Na+-Loaded Frog Sartorius Muscle

A model for the Na-K exchange pump was applied to data on Na⁺-loaded frog sartorius muscle, and was used to relate the rate of adenosine triphosphate (ATP) hydrolysis to the electrical properties of the cell membrane. Membrane hyperpolarization was considered to arise from an electrical current which was produced by the hydrolysis reaction coupled to ion movements, and which flowed across the membrane. The reaction rate, as calculated from hyperpolarization, agreed with direct measurements of ATP hydrolysis and with the rate estimated from Na⁺ tracer efflux studies. Although Na⁺ is actively extruded, the model showed that K⁺ is inwardly transported if the potassium permeability of the membrane is less than about 6.6 × 10^-6 cm/sec, as is suggested by resistance data. Calculations indicated that the reaction conductance L_rr was relatively constant when compared with the reaction rate and reaction free energy for large changes in internal and external ionic concentrations. Its value agreed with the value obtained from the dependence of Na⁺ tracer efflux on external K⁺. A set of experiments was suggested which would provide a more complete interpretation of the data.