Low molecular weight poly(A)+ mRNA species encode factors that modulate gating of a non-Shaker A-type K+ channel

Voltage-dependent K+ channels control repolarization of action potentials and help establish firing patterns in nerve cells. To determine the nature and role of molecular components that modulate K+ channel function in vivo, we coinjected Xenopus oocytes with cRNA encoding a cloned subthreshold A-type K+ channel (mShal1, also referred to as mKv4.1) and a low molecular weight (LMW) fraction (2-4 kb) of poly(A)+ mRNA (both from rodent brain). Coinjected oocytes exhibited a significant (fourfold) increase in the surface expression of mShal1 K+ channels with no change in the open-channel conductance. Coexpression also modified the gating kinetics of mShal1 current in several respects. Macroscopic inactivation of whole oocyte currents was fitted with the sum of two exponential components. Both fast and slow time constants of inactivation were accelerated at all membrane potentials in coinjected oocytes (tau f = 47.2 ms vs 56.5 ms at 0 mV and tau s = 157 ms vs 225 ms at 0 mV), and the corresponding ratios of amplitude terms were shifted toward domination by the fast component (Af/As = 2.71 vs 1.17 at 0 mV). Macroscopic activation was characterized in terms of the time-to-peak current, and it was found to be more rapid at all membrane potentials in coinjected oocytes (9.9 ms vs 13.5 ms at 0 mV). Coexpression also leads to more rapid recovery from inactivation (approximately 2.4-fold faster at -100 mV). The coexpressed K+ currents in oocytes resemble currents expressed in mouse fibroblasts (NIH3T3) transfected only with mShal1 cDNA. These results indicate that mammalian regulatory subunits or enzymes encoded by LMW mRNA species, which are apparently missing or expressed at low levels in Xenopus oocytes, may modulate gating in some native subthreshold A-type K+ channels.     

卵胞内微注射mRNA后胞膜上出现的新离子流

以胞内微注射技术向爪蟾卵内注射羊气管上皮细胞抽提的Poly(A)~ mRNA,以电压钳技术观察卵膜离子流的变化。注射前卵膜上主要有Ca~(2 ),Cl~-,K~ 和Na~ 流,在高钙溶液(10Ca-ND96)中,瞬间的Ca~(2 )激活Cl~-流较大,此离子流可被9-羟蒽阻断。注射mRNA后在9-羟蒽存在的情况下,向浴槽加入1mmol/L 8-Br-cAMP后新出现一个电压敏感的离子流,使电流电压曲线的零电流电位向右移;但在注射去离子水组未见此离子流。表明羊气管上皮里含有cAMP敏感的离子通道,并可被移植到爪蟾卵膜上。     

Tetrodotoxin-sensitive sodium current in native Xenopus oocytes

Depolarization of oocytes of Xenopus laevis usually elicits mainly passive currents, and a calcium-dependent chloride current. However, oocytes obtained from some donors show, in addition, a transient inward current on depolarization to potentials beyond ca. -40 mV. This current is abolished by tetrodotoxin at submicromolar concentrations, and is prolonged by veratrine; thus, it probably arises through sodium channels of a type similar to those found in nerve and muscle cells. However, the kinetics of the sodium currents varied between oocytes from different donors; this result suggests that genes encoding different sodium channels may be expressed in oocytes from different donors. The presence of these native channels may complicate experiments to study the expression of exogenous sodium channels encoded by foreign messenger RNAs injected into the oocyte.     

红藻氨酸和GABA受体在中华大蟾蜍卵母细胞的表达

本文报道了利用中华大蟾蜍卵母细胞作为外源性膜蛋白的表达及其功能特性研究的模式系统。将大鼠脑的mRNA微量注入蟾蜍卵母细胞(每个卵母细胞注射50ng),在19℃下经48h以上培养后,由外源mRNA表达的大鼠脑的红藻氨酸和γ-氨基丁酸受体被整合到了卵母细胞膜上。红藻氨酸(5×10~(-5)mol/L)和γ-氨基丁酸(10~(-4)mol/L)所诱导的膜电流分别达到294.0±6.4nA(n=5)和309.5±4.9nA(n=4)。红藻氨酸浓度在10~(-3)mol/L时,其诱导的膜电流达最大值。进而,注射mRNA的卵母细胞,~(36)Cl~-流入速度比对照组高一倍多。这些结果表明,中华大蟾蜍卵母细胞,如同爪蟾卵母细胞一样,能表达具有功能的外源膜蛋白(受体蛋白和离子运输蛋白)。     

Expression of Olfactory Receptors in Xenopus Oocytes

The rat olfactory epithelium and the amino acid-sensitive catfish olfactory system have been used as models to study the molecular mechanisms of olfactory transduction. Here we report the functional expression of rat and catfish olfactory receptors in Xenopus oocytes injected with mRNA isolated from the respective tissues. Application of odor ligands to injected oocytes, monitored by two-electrode voltage clamp, activates stimulus-dependent transmembrane currents that reverse direction at about the chloride equilibrium potential. The currents show characteristic secondary oscillations that are presumed to reflect underlying Ca2+ oscillations. Similar ligand-activated membrane currents induced in oocytes after injection of other mRNAs have been shown to be due to activation of endogenous Ca(2+)-activated chloride channels. In summary, our results demonstrate the usefulness of the Xenopus oocyte expression system for cloning and characterization of olfactory receptors in both fish and mammalian species.     

Induction of endogenous channels by high levels of heterologous membrane proteins in Xenopus oocytes.

Xenopus oocytes are widely employed for heterologous expression of cloned proteins, particularly electrogenic molecules such as ion channels and transporters. The high levels of expression readily obtained permit detailed investigations without interference from endogenous conductances. Injection of min K mRNA into Xenopus oocytes results in expression of voltage-dependent potassium-selective channels. Recent data show that injections of high concentrations of min K mRNA also induce a chloride current with very different biophysical, pharmacological, and regulatory properties from the min K potassium current. This led to the suggestion that the min K protein acts as an inducer of endogenous, normally silent oocyte ion channels. We now report that high levels of heterologous expression of many membrane proteins in Xenopus oocytes specifically induce this chloride current and a hyperpolarization-activated cation-selective current. The current is blocked by 4,4'-diisothiocyanostilbene-2-2'-disulphonic acid and tetraethylammonium, enhanced by clofilium, and is pH-sensitive. Criteria are presented that distinguish this endogenous current from those due to heterologous expression of electrogenic proteins in Xenopus oocytes. Together with structure-function studies, these results support the hypothesis that the min K protein comprises a potassium-selective channel.     

Cystic fibrosis transmembrane conductance regulator differentially regulates human and mouse epithelial sodium channels in Xenopus oocytes

The cystic fibrosis transmembrane conductance regulator (CFTR), in addition to its well defined Cl- channel properties, regulates other ion channels. CFTR inhibits murine or rat epithelial Na+ channel (mENaC or rENaC) currents in many epithelial and non-epithelial cells, whereas murine or rat ENaC increases CFTR functional expression. These regulatory interactions are reproduced in Xenopus oocytes where both the open probability and surface expression of wild type CFTR Cl- channels are increased when CFTR is co-expressed with alphabetagamma mENaC, and conversely the activity of mENaC is inhibited after wild type CFTR activation. Using the Xenopus oocyte expression system, differences in functional regulatory interactions were observed when CFTR was co-expressed with either alphabetagamma mENaC or alphabetagamma human ENaC (hENaC). Co-expression of CFTR and alphabetagamma mENaC or hENaC resulted in an approximately 3-fold increase in CFTR Cl- current compared with oocytes expressing CFTR alone. Oocytes co-injected with both CFTR and mENaC or hENaC expressed an amiloride-sensitive whole cell current that was decreased compared with that observed with the injection of mENaC or hENaC alone before CFTR activation with forskolin/3-isobutyl-1-methylxanthine. CFTR activation resulted in a further 50% decrease in mENaC-mediated currents, an approximately 20% decrease in alpha-T663-hENaC-mediated currents, and essentially no change in alpha-A663-hENaC-mediated currents. Changes in ENaC functional expression correlated with ENaC surface expression by oocyte surface biotinylation experiments. Assessment of regulatory interactions between CFTR and chimeric mouse/human ENaCs suggest that the 20 C-terminal amino acid residues of alpha ENaC confer species specificity regarding ENaC inhibition by activated CFTR.     

Effects of ethanol on three endogenous membrane conductances present in Xenopus laevis oocytes

The Xenopus oocyte expression and recording system has allowed a detailed analysis of the physiology and pharmacology of neuronal ion channels including their sensitivity to ethanol. It is important however, to ascertain the effects of a particular drug on the channels inherently expressed by oocytes to ensure that drug effects ascribed to the expressed recombinant receptors are manifested solely through those receptors. In this study, the effects of ethanol were determined on three endogenous currents that can be elicited in oocytes and other cells by various manipulations. The inward cation current, IC, was activated by perfusing naive oocytes with a divalent-free recording solution. Ethanol (25-100 mM) modestly inhibited IC with 100 mM ethanol producing a 7-8% inhibition of steady state currents. The store-operated or capacitative calcium current (I(SOC)) was activated in thapsigargin-treated oocytes by switching from a calcium-free solution to one containing 10 mM calcium. In thapsigargin-treated oocytes also injected with EGTA to block calcium-activated chloride currents, ethanol (100 mM) had no effect on the store-operated calcium current. In contrast, ethanol (10-100 mM) dose-dependently inhibited the calcium-dependent chloride current (I(Cl(Ca)) in thapsigargin-treated oocytes. A voltage-jump protocol was used to separate the two components of I(Cl(Ca)), I(Cl-1) and I(Cl-2). Under these conditions, ethanol (100 mM) inhibited I(Cl-1) currents to a greater extent (38%) than it did I(Cl-2) currents (14%). These results show that Xenopus oocytes express endogenous ion channels that are differentially sensitive to ethanol.     

Xenopus connexin38 forms hemi-gap-junctional channels in the nonjunctional plasma membrane of Xenopus oocytes.

A nonselective cation current activated by depolarization (Ic) is present in the nonjunctional membrane of Xenopus oocytes. This current shares a number of properties with hemi-gap-junctional currents induced by exogenous gap-junctional proteins in oocytes and with a nonjunctional current seen in teleost retinal horizontal cells including nonselective permeability to small cations, block by external divalent cations, and slow activation kinetics. Here we study the effects of depleting or overexpressing Cx38 on Ic. Antisense depletion of Cx38 caused a marked reduction in Ic and blocked endogenous gap-junctional coupling in oocyte pairs. Conversely, expression of cloned Cx38 in oocytes increased the amplitude of Ic and enhanced gap-junctional coupling. Furthermore, there appeared to be a close correlation between the temperature sensitivity of Ic and the temperature sensitivity of assembly of endogenous gap-junctional channels in oocyte pairs. These results suggest that Xenopus connexin38 is involved in the generation of Ic.     

Changes in intracellular calcium and in membrane currents evoked by injection of inositol trisphosphate into Xenopus oocytes

Intracellular calcium was monitored by the use of aequorin in voltage-clamped oocytes of Xenopus laevis. Injection of inositol trisphosphate (IP3) into oocytes elicited slowly rising and decaying aequorin/calcium signals and produced oscillatory chloride membrane currents. These responses did not depend upon extracellular calcium, since they could be elicited in calcium-free solution and after addition of cobalt or lanthanum to block calcium channels in the surface membrane. We conclude that IP3 causes the release of calcium from intracellular stores in the oocyte. Injections of calcium gave aequorin and membrane current responses that were more transient than those seen with IP3.     

Membrane currents in the oocyte of the toad Bufo arenarum

The amphibian oocyte cell model is widely used for heterologous expression of ionic channels and receptors. Little is known, however, about the physiology of oocyte cell models other than Xenopus laevis. In this study, the two-electrode voltage clamp technique was used to assess the most common electrical patterns of oocytes of the South American toad Bufo arenarum. Basal membrane resistance, resting potential, and ionic currents were determined in this cell model. The oocyte transmembrane resistance was 0.35 M(Omega), and the resting potential in normal saline was about -33 mV with a range between -20 mV and -50 mV. This is, to our knowledge, the first attempt to begin an understanding of the ion transport mechanisms of Bufo arenarum oocytes. This cell model may provide a viable alternative to the expression of ion channels, in particular those endogenously observed in Xenopus laevis oocytes.     

Serotonin receptors induced by exogenous messenger RNA in Xenopus oocytes

When poly(A)+-mRNA, extracted from rat brain, was injected into Xenopus laevis oocytes, it induced the appearance of serotonin receptors in the oocyte membrane. Application of serotonin to injected oocytes elicited, after a long delay, oscillations in membrane current. The equilibrium potential of this current corresponded with the chloride equilibrium potential. It appears that rat brain mRNA encodes the translation of serotonin receptors into the oocyte membrane. The combination of serotonin with these receptors leads to the opening of membrane channels.     

Progesterone treatment abolishes exogenously expressed ionic currents in Xenopus oocytes

Fully grown oocytes of Xenopus laevis undergo resumption of the meiotic cycle when treated with the steroid hormone progesterone. Previous studies have shown that meiotic maturation results in profound downregulation of specific endogenous membrane proteins in oocytes. To determine whether the maturation impacts the functional properties of exogenously expressed membrane proteins, we used cut-open recordings from Xenopus oocytes expressing several types of Na(+) and K(+) channels. Treatment of oocytes with progesterone resulted in a downregulation of heterologously expressed Na(+) and K(+) channels without a change in the kinetics of the currents. The time course of progesterone-induced ion channel inhibition was concentration dependent. Complete elimination of Na(+) currents temporally coincided with development of germinal vesicle breakdown, while elimination of K(+) currents was delayed by approximately 2 h. Coexpression of human beta(1)-subunit with rat skeletal muscle alpha-subunit in Xenopus oocytes did not prevent progesterone-induced downregulation of Na(+) channels. Addition of 8-bromo-cAMP to oocytes or injection of heparin before progesterone treatment prevented the loss of expressed currents. Pharmacological studies suggest that the inhibitory effects of progesterone on expressed Na(+) and K(+) channels occur downstream of the activation of cdc2 kinase. The loss of channels is correlated with a reduction in Na(+) channel immunofluorescence, pointing to a disappearance of the ion channel-forming proteins from the surface membrane.     

ATP crossing the cell plasma membrane generates an ionic current in xenopus oocytes

The presence of ATP within cells is well established. However, ATP also operates as an intercellular signal via specific purinoceptors. Furthermore, nonsecretory cells can release ATP under certain experimental conditions. To measure ATP release and membrane currents from a single cell simultaneously, we used Xenopus oocytes. We simultaneously recorded membrane currents and luminescence. Here, we show that ATP release can be triggered in Xenopus oocytes by hyperpolarizing pulses. ATP release (3.2 +/- 0.3 pmol/oocyte) generated a slow inward current (2.3 +/- 0.1 microA). During hyperpolarizing pulses, the permeability for ATP(4-) was more than 4000 times higher than that for Cl(-). The sensitivity to GdCl(3) (0. 2 mm) of hyperpolarization-induced ionic current, ATP release and E-ATPase activity suggests their dependence on stretch-activated ion channels. The pharmacological profile of the current inhibition coincides with the inhibition of ecto-ATPase activity. This enzyme is highly conserved among species, and in humans, it has been cloned and characterized as CD39. The translation, in Xenopus oocytes, of human CD39 mRNA encoding enhances the ATP-supported current, indicating that CD39 is directly or indirectly responsible for the electrodiffusion of ATP.     

A recombinant inwardly rectifying potassium channel coupled to GTP- binding proteins

GTP-binding (G) proteins have been shown to mediate activation of inwardly rectifying potassium (K+) channels in cardiac, neuronal and neuroendocrine cells. Here, we report functional expression of a recombinant inwardly rectifying channel which we call KGP (or hpKir3.4), to signify that it is K+ selective, G-protein-gated and isolated from human pancreas. KGP expression in Xenopus oocytes resulted in sizeable basal (or agonist-independent) currents while coexpression with a G-protein-linked receptor, yielded additional agonist-induced currents. Coexpression of KGP and hGIRK1 (a human brain homolog of GIRK1/Kir3.1) produced much larger basal currents than those observed with KGP or hGIRK1 alone, and upon coexpression with receptor, similarly large agonist-induced currents could be obtained. Pertussis toxin treatment significantly diminished agonist-dependent currents due to either KGP or KGP/hGIRK1 expression. Interestingly, PTX also significantly reduced basal KGP or KGP/hGIRK1 currents, suggesting that basal activity is largely the result of G-protein gating as well. When the two channels were coexpressed with receptor, the relative increase in current elicited by agonist was similar whether KGP and hGIRK1 were expressed alone or together. When in vitro translated or when expressed in Xenopus oocytes or CHO mammalian cells, KGP gave rise to a nonglycosylated 45-kD protein. Antibodies directed against either KGP or hGIRK1 coprecipitated both proteins coexpressed in oocytes, providing evidence for the heteromeric assembly of the two channels and suggesting that the current potentiation seen with coexpression of the two channel subunits is due to specific interactions between them. An endogenous oocyte protein similar in size to KGP was also coprecipitated with hGIRK1.     

Characterization of a Shaw-related potassium channel family in rat brain.

Previously, we characterized a Shaker-related family of voltage-gated potassium channels (RCK) in rat brain. Now, we describe a second family of voltage-gated potassium channels in the rat nervous system. This family is related to the Drosophila Shaw gene and has been dubbed Raw. In contrast to the RCK potassium channel family the Raw family utilizes extensive alternative splicing for expressing potassium channel subunits with variant C-termini. These alternative C-termini do not appear to influence the electrophysiological and pharmacological properties as studied in the Xenopus oocyte expression system. In situ hybridizations to sections of rat brain indicate that members of the Raw family are expressed in distinct areas of the central nervous system. Probably, Raw channels are expressed predominantly as homomultimers. Immunocytochemical experiments with antibodies against Raw3 and RCK4 proteins which form two distinct A-type potassium channels indicate that in hippocampus the two channels are expressed both in different neurons and in the same ones. In general, properties of Raw potassium channels appeared to be similar to RCK channels. However, Raw outward currents, in contrast to RCK currents, exhibit an intense rectification at test potentials higher than +20 to +40 mV. RCK and Raw channel subunits did not measurably coassemble into RCK/Raw heteromultimers after coinjecting RCK and Raw cRNA into Xenopus oocytes. These results suggest that members of the RCK and the Raw potassium channel families express potassium channels which form independent outward current systems. Combining the results of in situ hybridizations, immunocytochemical staining and expression of the cloned potassium channels in Xenopus oocytes demonstrates that unrestrained mixing of potassium channel subunits to form hybrid channels does not occur in the rat central nervous system. A single neuron is able to express multiple, independently assembled potassium channels.     

RNA interference reveals that endogenous Xenopus MinK-related peptides govern mammalian K+ channel function in oocyte expression studies

The physiological properties of most ion channels are defined experimentally by functional expression of their pore-forming alpha subunits in Xenopus laevis oocytes. Here, we cloned a family of Xenopus KCNE genes that encode MinK-related peptide K(+) channel beta subunits (xMiRPs) and demonstrated their constitutive expression in oocytes. Electrophysiological analysis of xMiRP2 revealed that when overexpressed this gene modulates human cardiac K(+) channel alpha subunits HERG (human ether-a-go-go-related gene) and KCNQ1 by suppressing HERG currents and removing the voltage dependence of KCNQ1 activation. The ability of endogenous levels of xMiRP2 to contribute to the biophysical attributes of overexpressed mammalian K(+) channels in oocyte studies was assessed next. Injection of an xMiRP2 sequence-specific short interfering RNA (siRNA) oligo reduced endogenous xMiRP2 expression 5-fold, whereas a control siRNA oligo had no effect, indicating the effectiveness of the RNA interference technique in Xenopus oocytes. The functional effects of endogenous xMiRP2 silencing were tested using electrophysiological analysis of heterologously expressed HERG channels. The RNA interference-mediated reduction of endogenous xMiRP2 expression increased macroscopic HERG current as much as 10-fold depending on HERG cRNA concentration. The functional effects of human MiRP1 (hMiRP1)/HERG interaction were also affected by endogenous xMiRP2. At high HERG channel density, at which the effects of endogenous xMiRP2 are minimal, hMiRP1 reduced HERG current. At low HERG current density, hMiRP1 paradoxically up-regulated HERG current, a result consistent with hMiRP1 rescuing HERG from suppression by endogenous xMiRP2. Thus, endogenous Xenopus MiRP subunits contribute to the base-line properties of K(+) channels like HERG in oocyte expression studies, which could explain expression level- and expression system-dependent variation in K(+) channel function.     

Expression of an outward-rectifying potassium channel from maize mRNA and complementary RNA in Xenopus oocytes.

Injection of Xenopus oocytes with poly(A)+ mRNA isolated from different plants (maize, cucumber, and squash) results in the appearance of a voltage- and time-dependent, potassium-selective, outward current that is similar to the outward-rectifying potassium current recorded in many higher plant cells. Maize shoots were found to be especially enriched in mRNA encoding such activity. A cDNA library of maize shoot mRNA was constructed in the vector lambda ZAPII and was used to synthesize RNA complementary to the cDNA (cRNA). Injection of the cRNA gave rise to an outward-rectifying potassium current with properties similar to the currents obtained by poly(A)+ mRNA injection. These results demonstrate that higher plant mRNA can be properly translated into a product that produces a voltage-regulated potassium channel in the plasma membrane of Xenopus oocytes. Thus, Xenopus oocytes can be used as a heterologous expression system for the functional identification and isolation of plant ion channel genes as well as for the study of structure-function relationship of plant ion channels.