Wanderlust kinetics and variable Ca(2+)-sensitivity of Drosophila, a large conductance Ca(2+)-activated K+ channel, expressed in oocytes

Cloned large conductance Ca(2+)-activated K+ channels (BK or maxi-K+ channels) from Drosophila (dSlo) were expressed in Xenopus oocytes and studied in excised membrane patches with the patch-clamp technique. Both a natural variant and a mutant that eliminated a putative cyclic AMP-dependent protein kinase phosphorylation site exhibited large, slow fluctuations in open probability with time. These fluctuations, termed "wanderlust kinetics," occurred with a time course of tens of seconds to minutes and had kinetic properties inconsistent with simple gating models. Wanderlust kinetics was still observed in the presence of 5 mM caffeine or 50 nM thapsigargin, or when the Ca2+ buffering capacity of the solution was increased by the addition of 5 mM HEDTA, suggesting that the wanderlust kinetics did not arise from Ca2+ release from caffeine and thapsigargin sensitive internal stores in the excised patch. The slow changes in kinetics associated with wanderlust kinetics could be generated with a discrete-state Markov model with transitions among three or more kinetic modes with different levels of open probability. To average out the wanderlust kinetics, large amounts of data were analyzed and demonstrated up to a threefold difference in the [Ca2+]i required for an open probability of 0.5 among channels expressed from the same injected mRNA. These findings indicate that cloned dSlo channels in excised patches from Xenopus oocytes can exhibit large variability in gating properties, both within a single channel and among channels.

Inhibitory interactions between two inward rectifier K+ channel subunits mediated by the transmembrane domains

Inwardly rectifying K+ channel subunits may form homomeric or heteromeric channels with distinct functional properties. Hyperpolarizing commands delivered to Xenopus oocytes expressing homomeric Kir 4.1 channels evoke inwardly rectifying K+ currents which activate rapidly and undergo a pronounced decay at more hyperpolarized potentials. In addition, Kir 4.1 subunits form heteromeric channels when coexpressed with several other inward rectifier subunits. However, coexpression of Kir 4.1 with Kir 3.4 causes an inhibition of the Kir 4.1 current. We have investigated this inhibitory effect and show that it is mediated by interactions between the predicted transmembrane domains of the two subunit classes. Other subunits within the Kir 3.0 family also exhibit this inhibitory effect which can be used to define subgroups of the inward rectifier family. Further, the mechanism of inhibition is likely due to the formation of an "inviable complex" which becomes degraded, rather than by formation of stable nonconductive heteromeric channels. These results provide insight into the assembly and regulation of inwardly rectifying K+ channels and the domains which define their interactions.

Episodic ataxia results from voltage-dependent potassium channels with altered functions

Episodic ataxia (EA) is an autosomal dominant human disorder that produces persistent myokymia and attacks of generalized ataxia. Recently, familial EA has been linked to the voltage-dependent delayed rectifier, Kv1.1, on chromosome 12. Six EA families have been identified that carry distinct Kv1.1 missense mutations; all individuals are heterozygous. Expression in Xenopus oocytes demonstrates that two of the EA subunits form homomeric channels with altered gating properties. V408A channels have voltage dependence similar to that of wild-type channels, but with faster kinetics and increased C-type inactivation, while the voltage dependence of F184C channels is shifted 20 mV positive. The other four EA subunits do not produce functional homomeric channels but reduce the potassium current when coassembled with wild-type subunits. The results suggest a cellular mechanism underlying EA in which the affected nerve cells cannot efficiently repolarize following an action potential because of altered delayed rectifier function.

Imidazoline compounds inhibit KATP channels in guinea pig ventricular myocytes

Phentolamine and related imidazolines inhibit KATP channel activity in the pancreatic beta cell. In the present study, the effects of several imidazoline-based compounds were examined upon KATP channel activity in guinea pig ventricular myocytes. Phentolamine produced a potent inhibition of KATP channel activity when examined in either excised inside-out patches or in the whole-cell configuration. This effect was unrelated to phentolamine's ability to antagonise alpha-adrenoceptors since the nonselective alpha-adrenoceptor antagonists, benextramine and phenoxybenzamine, failed to affect channel activity. Furthermore, the alpha-adrenoceptor agonist clonidine together with several related imidazolines inhibited channel activity. This suggests that imidazoline compounds modulate KATP channel activity in guinea pig ventricular myocytes and this may have clinical implications for the use of such agents as hypoglycemic drugs.

min K channels form by assembly of at least 14 subunits

Injection of min K mRNA into Xenopus oocytes results in expression of slowly activating voltage-dependent potassium channels, distinct from those induced by expression of other cloned potassium channels. The min K protein also differs in structure, containing only a single predicted transmembrane domain. While it has been demonstrated that all other cloned potassium channels form by association of four independent subunits, the number of min K monomers which constitute a functional channel is unknown. In rat min K, replacement of Ser-69 by Ala (S69A) causes a shift in the current-voltage (I-V) relationship to more depolarized potentials; currents are not observed at potentials negative to 0 mV. To determine the subunit stoichiometry of min K channels, wild-type and S69A subunits were coexpressed. Injections of a constant amount of wild-type mRNA with increasing amounts of S69A mRNA led to potassium currents of decreasing amplitude upon voltage commands to -20 mV. Applying a binomial distribution to the reduction of current amplitudes as a function of the different coinjection mixtures yielded a subunit stoichiometry of at least 14 monomers for each functional min K channel. A model is presented for how min K subunits may form a channel.

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.

Three gonadotropin-releasing hormone genes in one organism suggest novel roles for an ancient peptide

Gonadotropin-releasing hormone (GnRH) is known and named for its essential role in vertebrate reproduction. Release of this decapeptide from neurons in the hypothalamus controls pituitary gonadotropin levels which, in turn, regulate gonadal state. The importance of GnRH is underscored by its widespread expression and conservation across vertebrate taxa: five amino acids are invariant in all nine known forms, whereas two others show only conservative changes. In most eutherian mammals, only one form, expressed in the hypothalamus, is thought to exist, although in a recent report, antibody staining in developing primates suggests an additional form. In contrast, multiple GnRH forms and expression loci have been reported in many non-mammalian vertebrates. However, evidence based on immunological discrimination does not always agree with analysis of gene expression, since GnRH forms encoded by different genes may not be reliably distinguished by antibodies. Here we report the expression of three distinct GnRH genes in a teleost fish brain, including the sequence encoding a novel GnRH preprohormone. Using in situ hybridization, we show that this form is found only in neurons that project to the pituitary and exhibit changes in soma size depending on social and reproductive state. The other two GnRH genes are expressed in other, distinct cell populations. All three genes share the motif of encoding a polypeptide consisting of GnRH and a GnRH-associated peptide. Whereas the GnRH moiety is highly conserved, the GnRH-associated peptides are not, reflecting differential selective pressure on different parts of the gene. GnRH forms expressed in nonhypothalamic regions may serve to coordinate reproductive activities of the animal.

No evidence for mutations in a putative subunit of the beta-cell ATP-sensitive potassium channel (K-ATP channel) in Japanese NIDDM patients

The ATP-sensitive K channel (K-ATP channel) in pancreatic beta cells is believed to play a crucial role in glucose-stimulated insulin release. We investigated whether defects in the recently cloned gene for a putative subunit of this channel (KATP-2) could be a cause of diabetes in Japanese patients. The coding region of this beta-cell type channel gene was investigated in 192 diabetics with a family history of the disorder by single-stranded conformational polymorphism (SSCP) analysis. Two silent polymorphisms were found and confirmed by sequencing, but no missense or nonsense mutations were detected. The allele frequency of the polymorphisms was compared with 96 control subjects without a family history of the disease, and no clear difference was found. These results indicate that genetic defects of the KATP-2 channel may not be a major cause of diabetes in Japan.

Proteins that interact with the pore-forming subunits of voltage-gated ion channels

Voltage-gated ion channels are composed of pore-forming subunits, as well as auxiliary subunits that modify the functions of these channels. In addition, the channels interact with other modulatory proteins in a more transient manner, although with significant effects on channel activity. Even though many second-messenger systems influence the voltage-gated ion channels, only in a few cases has clear evidence for direct protein-protein interactions been demonstrated. Recent biochemical and genetic studies have helped to elucidate the scope of the interactions between these ion channels and various modulatory proteins by determining the structures and functions of nonpore-forming subunits.

Contributions of the C-terminal domain to gating properties of inward rectifier potassium channels

Two inward rectifier potassium channels, the G protein-dependent GIRK1 and the G protein-independent BIR10, display large differences in rectification and macroscopic kinetics. A chimeric channel was constructed in which the putative intracellular carboxy-terminal domain of the G protein-dependent channel replaced the corresponding domain of the G protein-independent channel. The chimeric channel conducted potassium ions without the requirement of activated G proteins, yet displayed activation and deactivation kinetics and rectification properties similar to those of the G protein-dependent channel. The results demonstrate that structural elements in the C-terminus can independently control gating but not G protein signal transduction. The voltage dependence, time course, and kinetics of gating suggest a mechanism in which the pore may be occluded by reversible interactions with charged residues in the C-terminus.

A neuron-specific enhancer targets expression of the gonadotropin-releasing hormone gene to hypothalamic neurosecretory neurons

The molecular mechanisms specifying gene expression in individual neurons of the mammalian central nervous system have been difficult to study due to the cellular complexity of the brain and the absence of cultured model systems representing differentiated central nervous system neurons. We have developed clonal, differentiated, neuronal tumor cell lines of the hypothalamic GnRH-producing neurons by targeting tumorigenesis in transgenic mice. These cells (GT1 cells) provide a model system for molecular studies of GnRH gene regulation. Here we present the identification and characterization of a neuron-specific enhancer responsible for directing expression of the rat GnRH gene in GT1 hypothalamic neurons. This approximately 300 base pair (bp) upstream region (-1571 to -1863) confers enhancer activity to a short -173-bp GnRH promoter or to a heterologous promoter only in GT1 cells. The enhancer is bound by multiple GT1 nuclear proteins over its entire length. Deletion of more than 30 bp from either end dramatically reduces activity, and even large internal fragments carrying seven of the eight DNAse I-protected elements show decreased activity. Scanning replacement mutations demonstrate that several of the internal elements are required for activity of the enhancer. Thus, the GnRH gene is targeted to hypothalamic neurons by a complex multicomponent enhancer that relies on the interaction of multiple nuclear-protein binding enhancer elements.

Persistent activation of min K channels by chemical cross-linking

Expression of the structurally and functionally distinct min K channel in Xenopus oocytes results in voltage-dependent potassium currents that activate with a characteristic slow time course. Application of a membrane-impermeable chemical cross-linking agent to oocytes expressing min K decreased the time-dependent current, increased its rate of activation, and induced persistently activated inward and outward potassium currents. These effects required membrane depolarization, demonstrating use dependence. Persistently activated channels retained potassium selectivity and sensitivity to block by clofilium and barium. These results suggest that a major conformational change occurs during min K channel gating, which can be stabilized by chemical cross-linking, and are consistent with a model in which min K channels activate by voltage-dependent subunit aggregation.

A structural determinant of differential sensitivity of cloned inward rectifier K+ channels to intracellular spermine

Large subtype-specific differences in the sensitivity of cloned inward-rectifier K+ channels of the IRK1, BIR10 and ROMK1 subtype to being blocked by intracellular spermine (SPM) are described. It is shown, by site-directed mutagenesis, that the four orders of magnitude larger SPM sensitivity of BIR10 channels compared to ROMK1 channels may be explained by a difference in a single amino acid in the putative transmembrane segment TMII. This residue, a negatively charged glutamate in BIR10, is homologous to the residue in IRK1 and ROMK1 which has previously been shown to change gating properties and Mg2+ sensitivity. Differential block by physiological SPM concentrations is suggested as a major functional difference between subtypes of inward-rectifier K+ channels.

Functional differences among alternatively spliced variants of Slowpoke, a Drosophila calcium-activated potassium channel

The Slowpoke locus of Drosophila melanogaster encodes a family of alternatively spliced mRNAs which encode large conductance calcium-activated potassium channels. Variability residues in blocks of amino acids designated boxes A, C, E, G, and I. Oocytes were injected with cRNAs that had been chosen for direct functional comparison of single box differences. Single channel records from inside-out patches of oocyte membranes expressing A1 or A3 forms, E1 or E2 forms, and G2-G5 forms were analyzed and compared. The main functional difference between A1 and A3 was in unitary conductance, whereas the main difference in properties between E1 and E2 was in calcium sensitivity. Activation kinetics were different between G3 and G5, but not consistently in different A and E box backgrounds. The results indicate that alternative splicing of a common RNA precursor contributes to the functional diversity of the expressed channel. Our findings suggest that the variable region of the Slowpoke channel subunit comprises modular, yet interactive functional domains which influence the essential features of unit conductance, calcium sensitivity, and gating.

Cloning and functional expression of a rat heart KATP channel

Potassium channels that are ATP-sensitive (KATP) couple membrane potential to the metabolic status of the cell. KATP channels are inhibited by intracellular ATP and are stimulated by intracellular nucleotide diphosphates. KATP channels are important regulators of secretory processes and muscle contraction, and are targets for therapeutic treatment of type II diabetes by the inhibitory sulphonylureas and for hypertension by activators such as pinacidil. In cardiac tissue, KATP channels are central regulators of post-ischaemic cardioprotection. Electrophysiological and pharmacological characteristics vary among KATP channels recorded from diverse tissues suggesting extensive molecular heterogeneity. A complementary DNA encoding a KATP channel was isolated from rat heart using the polymerase chain reaction. We report here that the expressed channels possess all of the essential features of native cardiac KATP channels, including sensitivity to intracellular nucleotides. In addition the cloned channels are activated by the potassium channel opener, pinacidil, but are not inhibited by the sulphonylurea, glibenclamide.

The novel class III antiarrhythmics NE-10064 and NE-10133 inhibit IsK channels expressed in Xenopus oocytes and IKs in guinea pig cardiac myocytes

Slowly activating, voltage-dependent IsK channels were expressed in Xenopus oocytes after injection of rat IsK protein cRNA and recorded with the two-microelectrode voltage-clamp technique. The IsK currents were inhibited by the new class III antiarrhythmic drugs NE-10064 and NE-10133. These compounds were equally potent in inhibiting a slowly activating potassium current (IKs) in guinea pig ventricular myocytes. No effects of these compounds could be observed on several other cloned delayed rectifier potassium channels, nor did they affect the inward rectifier current, IK1, in guinea pig cardiac myocytes at the concentrations tested. The blockade of IsK channels may contribute to the class III antiarrhythmic efficacy of these novel antiarrhythmics.

Cloned Ca(2+)-dependent K+ channel modulated by a functionally associated protein kinase

Calcium-dependent potassium (KCa) channels carry ionic currents that regulate important cellular functions. Like some other ion channels, KCa channels are modulated by protein phosphorylation. The recent cloning of complementary DNAs encoding Slo KCa channels has enabled KCa channel modulation to be investigated. We report here that protein phosphorylation modulates the activity of Drosophila Slo KCa channels expressed in Xenopus oocytes. Application of ATP-gamma S to detached membrane patches increases Slo channel activity by shifting channel voltage sensitivity. This modulation is blocked by a specific inhibitor of cyclic AMP-dependent protein kinase (PKA). Mutation of a single serine residue in the channel protein also blocks modulation by ATP-gamma S, demonstrating that phosphorylation of the Slo channel protein itself modulates channel activity. The results also indicate that KCa channels in oocyte membrane patches can be modulated by an endogenous PKA-like protein kinase which remains functionally associated with the channels in the detached patch.

Opening of large-conductance calcium-activated potassium channels by the substituted benzimidazolone NS004

1. We used electrophysiological techniques to examine the effects of 5-trifluoromethyl-1-(5-chloro-2-hydroxyphenyl)-1,3-dihydro-2H-benzimidaz ole- 2-one (NS004) on large-conductance calcium-activated potassium (BK) channels. 2. We used recordings from excised membrane patches (cell-attached and inside-out single-channel configurations) and whole-cell patch-clamp recordings to examine the effects of NS004 on single BK channels and whole-cell outward currents, respectively, in rat GH3 clonal pituitary tumor cells. We also tested NS004 on voltage-clamped BK channels isolated from rat brain plasma membrane preparations and reconstituted into planar lipid bilayers. Finally, we used two-electrode voltage-clamp techniques to study the effects of NS004 on currents expressed in Xenopus laevis oocytes by the recently described Slo BK clone from Drosophila. 3. In GH3 cells and in Xenopus oocytes expressing the Slo gene product NS004 produced an increase in an iberiotoxin- or tetraethylammonium-sensitive whole-cell outward current, respectively. NS004 produced a significant increase in the activity of single GH3 cell BK channels and rat brain BK channels reconstituted into planar lipid bilayers. In both systems this was characterized by an increase in channel mean open time, a decrease in interburst interval, and an apparent increase in channel voltage/calcium sensitivity. 4. These data indicate that NS004 could be useful for investigating the biophysical and molecular properties of BK channels and for determining the functional consequences of the opening of BK channels.

Reconstitution of expressed KCa channels from Xenopus oocytes to lipid bilayers

Reconstitution of large conductance calcium-activated potassium (KCa) channels from native cell membranes into planar lipid bilayers provides a powerful method to study single channel properties, including ion conduction, pharmacology, and gating. Recently, KCa channels derived from the Drosophila Slowpoke (Slo) gene have been cloned and heterologously expressed in Xenopus oocytes. In this report, we describe the reconstitution of cloned and expressed Slo KCa channels from Xenopus oocyte membranes into lipid bilayers. The reconstituted channels demonstrate functional properties characteristic of native KCa channels. They possess a mean unitary conductance of approximately 260 pS in symmetrical potassium (250 mM), and they are voltage- and calcium-sensitive. At 50 microM Ca2+, their half-activation potential was near -20 mV; and their affinity for calcium is in the micromolar range. Reconstituted Slo KCa channels were insensitive to external charybdotoxin (40-500 nM) and sensitive to micromolar concentrations of external tetraethylammonium (KD = 158 microM, at 0 mV) and internal Ba2+ (KD = 76 microM, at 40 mV). In addition, they were blocked by internally applied "ball" inactivating peptide (KD = 480 microM, at 40 mV). These results demonstrate that cloned KCa channels expressed in Xenopus oocytes can be readily incorporated into lipid bilayers where detailed mechanistic studies can be performed under controlled internal and external experimental conditions.

Tetraethylammonium block of Slowpoke calcium-activated potassium channels expressed in Xenopus oocytes: evidence for tetrameric channel formation

Unitary currents were recorded from inside-out membrane patches pulled from Xenopus oocytes that had been injected with RNA transcribed from a cDNA encoding the Drosophila maxi-K channel (Slowpoke). Site-directed mutagenesis was used to make cDNAs encoding channel subunits with single amino acid substitutions (Y308V and C309P). The extracellular side of the patch was exposed to tetraethylammonium (TEA) in the pipette solution; unitary currents in the presence of TEA were compared with currents in the absence of TEA to compute the inhibition. Amplitude distributions were fit by beta functions to estimate the blocking and unblocking rate constants. For wild-type channels, TEA blocked with an apparent Kd of 80 microM at 0 mV and sensed 0.18 of the membrane electric field; the voltage dependence lay entirely in the blocking rate constant. TEA blocked currents through C309P channels with a similar affinity to wild-type at 0 mV, but this was not voltage-dependent. Currents through Y308V channels were very insensitive to any block by TEA; the apparent Kd at 0 mV was 26 mM and the blockade sensed 0.18 of the electric field. Oocytes injected with a mixture of RNAs encoding wild-type and Y308V channels showed unitary currents of four discrete amplitudes in the presence of 3 mM TEA; at 40 mV these corresponded to inhibitions of approximately 80%, 55%, 25% and 10%.(ABSTRACT TRUNCATED AT 250 WORDS)

A second gene for gonadotropin-releasing hormone: cDNA and expression pattern in the brain

In vertebrates, the gonadotropin-releasing hormone (GnRH) decapeptide is secreted from hypothalamic nerve terminals to regulate reproduction via control of synthesis and release of pituitary gonadotropins. Only one GnRH peptide has been found in mammals, with one exception, although numerous other vertebrate species express more than one of the eight known decapeptide forms as shown by immunocytochemical labeling of distinct cell groups in the brain. However, neither the functional nor the evolutionary relationships among these GnRH forms are clear, because only one preprohormone gene sequence from any species has been reported. The most ubiquitous alternative form of GnRH is [His5,Trp7,Tyr8]GnRH (also referred to as chicken-II), which differs from the mammalian sequence at amino acids 5, 7, and 8. This peptide has been shown to have the most potent releasing-hormone activity, although immunocytochemical staining has suggested it is synthesized only in the mesencephalon. Here we report the cloning and expression pattern of the gene for the precursor of this form from the teleost fish Haplochromis burtoni. This is the second GnRH-encoding gene to be characterized in this species. The newly discovered preprohormone gene differs from that previously reported in two ways. First, whereas the original gene predicts only a single associated peptide, this one predicts two associated peptides, both of which appear to be unique. Second, the gene for [His5,Trp7,Tyr8]GnRH is expressed in only one cell group in the mesencephalon. In contrast, the previously reported gene is expressed only in the terminal nerve. The striking differences between the preprohormone structure and localization suggest that the genes coding for the two known GnRH forms in H. burtoni did not arise from a recent duplication event. Interestingly, neither of the two genes found to date in this species is expressed in cells which project from the hypothalamus to the pituitary, suggesting that yet a third gene coding for GnRH may exist.

The min K channel underlies the cardiac potassium current IKs and mediates species-specific responses to protein kinase C

A clone encoding the guinea pig (gp) min K potassium channel was isolated and expressed in Xenopus oocytes. The currents, gpIsK, exhibit many of the electrophysiological and pharmacological properties characteristic of gpIKs, the slow component of the delayed rectifier potassium conductance in guinea pig cardiac myocytes. Depolarizing commands evoke outward potassium currents that activate slowly, with time constants on the order of seconds. The currents are blocked by the class III antiarrhythmic compound clofilium but not by the sotalol derivative E4031 or low concentrations of lanthanum. Like IKs in guinea pig myocytes, gpIsK is modulated by stimulation of protein kinase A and protein kinase C (PKC). In contrast to rat and mouse IsK, which are decreased upon stimulation of PKC, myocyte IK and gpIsK in oocytes are increased after PKC stimulation. Substitution of an asparagine residue at position 102 by serine (N102S), the residue found in the analogous position of the mouse and rat min K proteins, results in decreased gpIsK in response to PKC stimulation. These results support the hypothesis that the min K protein underlies the slow component of the delayed rectifier potassium current in ventricular myocytes and account for the species-specific responses to stimulation of PKC.

Single amino acid substitution affects desensitization of the 5-hydroxytryptamine type 3 receptor expressed in Xenopus oocytes

5-Hydroxytryptamine type 3 receptors were expressed in Xenopus oocytes from a cloned cDNA. The peak inward current evoked by 5-hydroxytryptamine (30 microM) was linearly related to the holding potential (-100 to +20 mV) and reversed near 0 mV. The inward current (at -60 mV) declined during the continued presence of 5-hydroxytryptamine with a half-time of about 2 s; this desensitization was 20 times slower in calcium-free solution. Desensitization was markedly different in channels in which Leu286 was changed by site-directed mutagenesis; this residue is thought to lie near the middle of the M2 segment. Desensitization was faster with Phe, Tyr, or Ala in this position and slower with Thr. Phe and Thr substitutions in the equivalent position of the nicotinic acetylcholine receptor have similar effects on desensitization, suggesting that the underlying conformational change might be common to ligand-gated channels.

Cooperative interactions among subunits of a voltage-dependent potassium channel. Evidence from expression of concatenated cDNAs

Four copies of the coding sequence for a voltage-dependent potassium channel (RBK1, rat Kv1.1) were ligated contiguously and transcribed in vitro. The resulting RNA encodes four covalently linked subunit domains ([4]RBK1). Injection of this RNA into Xenopus oocytes resulted in the expression of voltage-dependent potassium currents. A single amino acid substitution, Tyr-->Val, located within the outer mouth of the pore, introduced into the equivalent position of any of the four domains, reduced affinity for external tetraethylammonium by approximately the same amount. In constructs containing 0, 1, 2, 3, or 4 Tyr residues the free energy of binding tetraethylammonium was linearly related to the number of Tyr residues. A different amino acid substitution, Leu-->Ile, located in the S4 region, was made in the equivalent position of one, two, three, or four domains. The depolarization required for channel activation increased approximately linearly with the number of Ile residues, whereas models of independent gating of each domain predict marked nonlinearity. Expression of this concatenated channel provides direct evidence that voltage-dependent potassium channels have four subunits positioned symmetrically around a central permeation pathway and that these subunits interact cooperatively during channel activation.

Calcium-activated potassium channels expressed from cloned complementary DNAs

Calcium-activated potassium channels were expressed in Xenopus oocytes by injection of RNA transcribed in vitro from complementary DNAs derived from the slo locus of Drosophila melanogaster. Many cDNAs were found that encode closely related proteins of about 1200 aa. The predicted sequences of these proteins differ by the substitution of blocks of amino acids at five identified positions within the putative intracellular region between residues 327 and 797. Excised inside-out membrane patches showed potassium channel openings only with micromolar calcium present at the cytoplasmic side; activity increased steeply both with depolarization and with increasing calcium concentration. The single-channel conductance was 126 pS with symmetrical potassium concentrations. The mean open time of the channels was clearly different for channels having different substituent blocks of amino acids. The results suggest that alternative splicing gives rise to a large family of functionally diverse, calcium-activated potassium channels.

Repulsion between tetraethylammonium ions in cloned voltage-gated potassium channels

Tetraethylammonium ion (TEA+) blocks voltage-gated K+ channels by acting at two sites located at opposite ends of the aqueous pore. This allowed us to test two predictions made by models of ion permeation, namely that K+ channels can be simultaneously occupied by multiple ions and that the ions repel each other. We show that externally applied TEA+ antagonize block by internal TEA+ and vice versa. The antagonism is less than predicted for competitive binding, hence TEA+ may occupy both sites simultaneously. External TEA+ and internal TEA+ reduce each others affinity 4- to 5-fold. In addition, K+ antagonizes block by TEA+ at the opposite side of the membrane, and external TEA+ antagonizes is block by internal Ba2+. The antagonism between ions applied at opposite sides of the membrane may be common to all cations binding to K+ channels.

Partial characterization of the gonadotropin-releasing hormone (GnRH) gene transcript in the rat ovary

It has been hypothesized that GnRH or a GnRH-like peptide is produced in the rat ovary, but the presence of GnRH in the ovary has not been unequivocally demonstrated. This study was undertaken to determine whether the GnRH gene is expressed in the rat ovary and to compare the GnRH gene transcripts from the ovary and the hypothalamus. Twelve samples of total RNA from ovaries of individual rats were screened by reverse transcription-polymerase chain reaction (RT-PCR) for the presence of GnRH gene transcripts. Fragments of GnRH cDNA were amplified using pairs of specific primers. GnRH transcripts were detected in all the ovaries examined, and differed from hypothalamic GnRH transcripts in two ways: first, in the ovaries a greater proportion of GnRH transcripts contained intronic sequences; second, the major transcription start utilized in the ovary differed from that used in the hypothalamus. Although fully processed GnRH gene transcripts were detected by RT-PCR in both, ovary and hypothalamus, they were not detected in the ovary by Northern blot. The GnRH probe hybridized specifically to the predicted 0.6 kb transcript in the hypothalamus, and to a 3.3 kb transcript in the ovary. We conclude that in the ovary, most GnRH gene transcripts retain intronic sequences.

Regulation by second messengers of the slowly activating, voltage-dependent potassium current expressed in Xenopus oocytes

1. Voltage-clamp recordings of membrane current were made from Xenopus oocytes that had been injected with RNA which had been transcribed in vitro from a cloned complementary DNA. 2. Depolarization from -80 mV evoked outward potassium currents that developed very slowly. At -20 mV the time constant for activation was about 50 s, and at +40 mV about 6 s. 3. The potassium current was increased by the calcium ionophore A23187 or by intracellular injection of inositol 1,4,5-trisphosphate (IP3), each of which should increase the intracellular calcium concentration ([Ca2+]i). The current was decreased by injection of BAPTA (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid). The current was also reduced by phorbol esters; this effect was blocked by staurosporine. 4. In oocytes that had also been injected with RNA encoding the 5-hydroxytryptamine (5-HT2) receptor, 5-HT increased the potassium current. After caffeine pretreatment, to block the release of intracellular calcium, 5-HT decreased the current; this decrease was prevented by staurosporine. 5. It is concluded that the slowly activating, voltage-dependent potassium current expressed in Xenopus oocytes is increased by increases in [Ca2+]i and is decreased by activation of protein kinase C. Stimulation of 5-HT2 receptors can have both these effects, but the former normally predominates.

Hypotonic solution increases the slowly activating potassium current IsK expressed in xenopus oocytes

A slowly activating potassium current was expressed in Xenopus oocytes by injection of RNA transcribed from a rat kidney cDNA clone. Hypotonic solutions (160 mOsmol/l; control was 220 mOsmol/l) increased the current by increasing the rate of activation and by decreasing the depolarization needed to activate the current. This effect of hypotonicity was not observed in calcium-free solution, but was unaffected by staurosporine or the calmodulin antagonist W7. Cytochalasin D reduced the current and prevented the increase by hypotonic solution. The results suggest that the increase in this potassium current by hypotonic solution might result from calcium entry and changes in the actin network.

An amino acid mutation in a potassium channel that prevents inhibition by protein kinase C

A slowly activating, voltage-dependent potassium channel protein cloned from rat kidney was expressed in Xenopus oocytes. Two activators of protein kinase C, 1-oleoyl-2-acetyl-rac-glycerol and phorbol 12,13-didecanoate, inhibited the current. This inhibition was blocked by the kinase inhibitor staurosporine. Inhibition of the current was not seen in channels in which Ser103 was replaced by Ala, although other properties of the current were unchanged. These results indicate that inhibition of the potassium current results from direct phosphorylation of the channel subunit protein at Ser103.

Multiple subunits of a voltage-dependent potassium channel contribute to the binding site for tetraethylammonium

RNAs encoding a wild-type (RBK1) and a mutant (RBK1(Y379V,V381T); RBK1*) subunit of voltage-dependent potassium channels were injected into Xenopus oocytes. When expressed separately, they made homotetrameric channels that differed about 100-fold in sensitivity to tetraethylammonium (TEA). Mixtures of channels having one, two, or three low affinity subunits were expressed by injecting various proportions of RBK1 and RBK1* RNAs. The affinity for TEA of these three channel species was deduced by fitting concentration-response curves for the inhibition of potassium currents. DNAs were also concatenated to construct a sequence that encoded two connected subunits, and channels that contained four, two, or no TEA-sensitive subunits were expressed. The results suggest that bound TEA interacts simultaneously with all four subunits.

Identification of amino acid residues involved in dendrotoxin block of rat voltage-dependent potassium channels

alpha-Dendrotoxin (DTX) is a 60-amino acid peptide belonging to the family of mamba snake neurotoxins; it is a potent blocker of some but not all voltage-gated potassium currents. Potassium currents recorded from oocytes injected with cloned potassium channel RNAs also vary in sensitivity to DTX. Expression of channels that were chimeras of the DTX-sensitive channel RBK2 and the DTX-insensitive channel RGK5 showed that the putative extracellular loop between transmembrane domains S5 and S6 contributes strongly to DTX sensitivity. Mutation of two residues (Ala352Glu353) in this region of RBK1 to conform to those at equivalent positions in RGK5 (Pro374Ser375) reduced the potency of DTX about 70-fold, and the substitution of Tyr379 in RBK1 by its counterpart in RGK5 (His401) caused an additional 2.5-fold decrease in sensitivity. Converse substitutions in RGK5 significantly increased sensitivity to DTX. The results suggest that these residues contribute significantly to the channel-toxin interaction, providing further evidence that the S5-S6 loop lies at or near the external mouth of the channel, where DTX binding leads to channel occlusion. They offer a molecular explanation for the differences in DTX sensitivity observed among native potassium channels.

Current inactivation involves a histidine residue in the pore of the rat lymphocyte potassium channel RGK5

RGK5 is a rat genomic DNA clone that encodes the n-type potassium channel found in T-lymphocytes and other cells. Current through this channel declines (inactivates) over a period of hundreds of milliseconds during a maintained depolarizing pulse, whether in lymphocytes or when expressed in Xenopus oocytes. Here we demonstrate that an amino acid residue near the outer pore of the channel, histidine401, is involved in the inactivation process. Replacement of this residue by tyrosine, the amino acid found in the equivalent position of the homologous but non-inactivating channel RBK1, reduced inactivation of RGK5 over a 5 s depolarizing pulse from 84.3 +/- 1.9% to 18.3 +/- 1.1%. Conversely, replacement of this tyrosine in RBK1 (Tyr379) by histidine increased its inactivation from 21.6 +/- 1.1% to 42.3 +/- 1.5%. These results suggest a mechanism of channel inactivation distinct from that previously described for the A-type potassium channel.

Transmitter regulation of voltage-dependent K+ channels expressed in Xenopus oocytes

Voltage-dependent K+ channels (RBK1, RBK2 and RGK5) were co-expressed in Xenopus oocytes with 5-hydroxytryptamine (5-HT2) receptors. K+ currents measured 2-4 days later were inhibited by 5-HT (100 nM-10 microM, 20-30 s application) by up to 90%. The effect of 5-HT was mimicked by intracellular injection of Ins(1,4,5)P3. Increasing the Ca2+ concentration at the inner surface of excised membrane patches did not decrease the K+ current.

Characterization of complementary DNA encoding the precursor for gonadotropin-releasing hormone and its associated peptide from a teleost fish

Reproductive maturity among male African cichlids Haplochromis burtoni is cued by a series of environmental and social interactions and is mediated physiologically by GnRH. A cDNA clone encoding the precursor for GnRH was isolated from this teleost. The molecular architecture of the predicted prohormone is analogous to that of the previously characterized mammalian forms; however, the predicted sequence of the associated peptide is strikingly different. Attempts to isolate a putative second precursor using low stringency hybridization were not successful despite evidence that a second related decapeptide exists in at least some teleost species.

A heparin sulfate-regulated human keratinocyte autocrine factor is similar or identical to amphiregulin

A novel human keratinocyte-derived autocrine factor (KAF) was purified from conditioned medium by using heparin affinity chromatography as the first step. Purified KAF stimulated the growth of normal human keratinocytes, mouse AKR-2B cells, and a mouse keratinocyte cell line (BALB/MK). Heparin sulfate inhibited KAF mitogenic activity on all cell types tested and inhibited the ability of KAF to compete with epidermal growth factor for cell surface binding. Interestingly, KAF stimulated the growth of BALB/MK cells at high cell density but failed to stimulate these cells at clonal density. Protein microsequencing of the first 20 NH2-terminal amino acid residues of purified KAF revealed identity to the NH2 terminus of human amphiregulin (AR). Northern (RNA) blot analysis with AR-specific cRNA demonstrated that human keratinocytes, as well as mammary epithelial cell cultures, expressed high levels of AR mRNA. In contrast, AR mRNA was not detected in normal human fibroblasts or melanocytes and was present at reduced levels in several mammary tumor cell lines. The mitogenic activity of purified AR was also shown to be inhibited by heparin sulfate, and an AR-specific enzyme-linked immunosorbent assay (ELISA) revealed that KAF and AR are antigenically related. We have previously shown that human keratinocytes can grow in an autocrine manner. Our present study demonstrates that one of the growth factors responsible for this autocrine growth (KAF) is similar or identical to AR and that KAF and AR bioactivity can be negatively regulated by heparin sulfate.

Interaction between tetraethylammonium and amino acid residues in the pore of cloned voltage-dependent potassium channels

Extracellular tetraethylammonium (TEA) inhibits currents in Xenopus oocytes that have been injected with mRNAs encoding voltage-dependent potassium channels. Concentration-response curves were used to measure the affinity of TEA; this differed up to 700-fold among channels RBK1 (KD 0.3 mM), RGK5 (KD 11 mM), and RBK2 (KD greater than 200 mM). Studies in which chimeric channels were expressed localized TEA binding to the putative extracellular loop between trans-membrane domains S5 and S6. Site-directed mutagenesis of residues in this region identified the residue Tyr379 of RBK1 as a crucial determinant of TEA sensitivity; substitution of Tyr in the equivalent positions of RBK2 (Val381) and RGK5 (His401) made these channels as sensitive to TEA as RBK1. Nonionic forces are involved in TEA binding because (i) substitution of the Phe for Tyr379 in RBK1 increased its affinity, (ii) protonation of His401 in RGK5 selectively reduced its affinity, and (iii) the affinity of TEA was unaffected by changes in ionic strength. The results suggest an explanation for the marked differences in TEA sensitivity that have been observed among naturally occurring and cloned potassium channels and indicate that the amino acid corresponding to residue 379 in RBK1 lies within the external mouth of the ion channel.

The hypothalamic-pituitary axis of streptozotocin-induced diabetic female rats is not normalized by estradiol replacement

Studies in diabetic rats have found abnormalities at the hypothalamic, pituitary, and/or ovarian level but have not controlled for changes in estrogen levels induced by diabetes. The purpose of this investigation was to study the effect of diabetes on the hypothalamic-pituitary axis in ovariectomized rats treated with estradiol (E2). Ovariectomized 60 day old female rats were assigned to control (C, n = 42), diabetic (D, n = 47) or insulin-treated diabetic (DI, n = 16) groups. Diabetes was induced with an injection of streptozotocin in the D and DI groups. In the C, D, and DI groups, estrogen was replaced by implanting blank, 5 micrograms or 20 micrograms E2 pellets sc. Pituitary LH responsiveness to GnRH was assessed in C and D animals. Anterior hypothalamic and midhypothalamic concentrations of proGnRH and GnRH, pituitary LH and FSH and serum levels of LH, and E2 were measured by RIA. Anterior hypothalamic proGnRH concentrations were decreased in diabetic rats treated with 5 micrograms E2 compared to 5 micrograms E2 control animals (P less than 0.05). Midhypothalamic GnRH concentrations were also reduced in D vs. C animals despite comparable estrogen therapy (P less than 0.004). GnRH-stimulated LH levels were greater in E2-treated diabetic females than in similarly treated control rats (P less than 0.001). D and DI animals were more sensitive than controls to the inhibitory effect of estrogen on basal LH levels. Pituitary LH and FSH content was lower in 20 micrograms E2-replaced animals but was not influenced by the diabetic state. These data demonstrate a diabetes-induced decrease in hypothalamic proGnRH and GnRH concentration which is not corrected with E2 replacement. The hyper-responsiveness of the diabetic rat pituitary to GnRH also suggests a chronic lack of GnRH stimulation from the hypothalamus but a continued ability of the pituitary to respond to GnRH.

Characterization and functional expression of a rat genomic DNA clone encoding a lymphocyte potassium channel

Low stringency hybridization screening of a rat genomic DNA library with a previously described cDNA clone encoding a rat voltage-gated potassium channel has resulted in the characterization of a member of the potassium channel family, RGK5. An uninterrupted nucleotide sequence encodes a protein 525 amino acids in length, revealing that the entire coding region resides on a single exon. RGK5 transcripts are present in both mouse thymus and rat brain, as determined by Northern blot analysis. RNA transcribed in vitro from RGK5 genomic DNA directs the expression of functional potassium currents after injection into Xenopus oocytes. The currents are activated by depolarization, being half-activated at -14 mV, and inactivate almost completely during depolarizations of 1 to 2 s. The properties of the currents strongly resemble those of the type n potassium channel present on both immature thymocytes and Th lymphocytes.

Characterization and functional expression of a rat genomic DNA clone encoding a lymphocyte potassium channel

Low stringency hybridization screening of a rat genomic DNA library with a previously described cDNA clone encoding a rat voltage-gated potassium channel has resulted in the characterization of a member of the potassium channel family, RGK5. An uninterrupted nucleotide sequence encodes a protein 525 amino acids in length, revealing that the entire coding region resides on a single exon. RGK5 transcripts are present in both mouse thymus and rat brain, as determined by Northern blot analysis. RNA transcribed in vitro from RGK5 genomic DNA directs the expression of functional potassium currents after injection into Xenopus oocytes. The currents are activated by depolarization, being half-activated at -14 mV, and inactivate almost completely during depolarizations of 1 to 2 s. The properties of the currents strongly resemble those of the type n potassium channel present on both immature thymocytes and Th lymphocytes.

Heteropolymeric potassium channels expressed in Xenopus oocytes from cloned subunits

Voltage-dependent potassium currents were measured in Xenopus oocytes previously injected with RNAs generated in vitro from each of three cloned cDNAs (RBK1, RBK2, and RGK5). The currents differed in their sensitivities to blockade by tetraethylammonium (TEA; respective KDs 0.3, greater than 100, and 10 mM) and in their inactivation during a depolarizing pulse. Injections of RNA combinations (RBK1/RBK2 and RBK1/RGK5) caused currents that had TEA sensitivities different from those expected from the sum, in any proportion, of the two native channels. It is concluded that novel potassium channels are formed by the oocytes injected with two RNAs, presumably by heteropolymerization of subunits; such heteropolymerization would contribute functional diversity to voltage-dependent potassium channels in addition to that provided by a large gene family.

Characterization of the rat prodynorphin gene

The structure of full-length rat prodynorphin cDNA and the corresponding gene has been determined. The 2400 base rat prodynorphin mRNA is encoded by four exons. Exons 1 and 2 encode the majority of the 5'-untranslated sequence, while exons 3 and 4 contain the translated region; the entire 3' -untranslated region is contained on exon 4 as well. RNase protection studies, in which a genomic DNA fragment was used to generate a cRNA hybridization probe, have determined the major transcriptional initiation site for both brain and testicular prodynorphin mRNA. Transient expression of transfected fusion genes containing the 5'-flanking DNA of the rat prodynorphin gene linked to the structural sequence of a reporter gene has been used to identify specific genomic DNA fragments from the prodynorphin gene locus which are capable of acting as transcriptional promoters. Multiple regions of genomic DNA appear to have transcriptional promoter activity when introduced into various eukaryotic cell lines.

Structure and expression of the human motilin gene

The human motilin gene was isolated from a human genomic library and its structure was determined by restriction mapping and DNA sequence analysis. The gene consists of five exons separated by four introns spanning approximately 9 kb of genomic DNA. Exon I encodes the 5' untranslated portion of the motilin mRNA. Exons II and III encode the signal peptide and the 22-amino-acid motilin peptide; codons encoding the motilin moiety are split by an intron. The carboxy-terminal motilin-associated peptide (MAP) is largely encoded by Exons III and IV with the last two amino acids of the motilin precursor and the 3' untranslated region encoded by Exon V. Thus, the motilin gene has an unusual structure in which a small bioactive peptide is encoded on two distinct exons. Examination of the expression of the human and nonhuman primate motilin gene by Northern hybridization analysis indicates that it is expressed in a number of gastrointestinal and extragastrointestinal tissues.

The rat gonadotropin-releasing hormone: SH locus: structure and hypothalamic expression

The rat GnRH gene as expressed in the central nervous system is comprised of four exons and three introns and spans 4.5 kilobases of genomic DNA. Recently it has been shown that the DNA strand opposite that which is transcribed to produce GnRH mRNA is transcribed in heart to produce a set of transcripts, SH RNAs, which share significant exonic sequences with the GnRH gene. The nucleotide sequence of this locus and approximately 3 kilobases on either side has been determined. Northern analysis of hypothalamic RNA probed with GnRH and SH strand specific probes demonstrate that both GnRH and SH RNAs are present within the preoptic hypothalamus. The cap sites for GnRH and SH transcripts have been localized using polymerase chain reaction technology. Results from these experiments indicate that in the preoptic hypothalamus GnRH transcription initiates from three sites. The majority of GnRH transcripts is spliced efficiently and gives rise to the major class of GnRH mRNA. A second spliced population is present in lower abundance, while a third population is not spliced. The SH gene contains at least two distinct promoters, from which two populations of transcripts are derived containing unique 5'-sequences spliced to a common 3'-region.

Expression of a cloned rat brain potassium channel in Xenopus oocytes

Potassium channels are ubiquitous membrane proteins with essential roles in nervous tissue, but little is known about the relation between their function and their molecular structure. A complementary DNA library was made from rat hippocampus, and a complementary DNA clone (RBK-1) was isolated. The predicted sequence of the 495-amino acid protein is homologous to potassium channel proteins encoded by the Shaker locus of Drosophila and differs by only three amino acids from the expected product of a mouse clone MBK-1. Messenger RNA transcribed from RBK-1 in vitro directed the expression of potassium channels when it was injected into Xenopus oocytes. The potassium current through the expressed channels resembles both the transient (or A) and the delayed rectifier currents reported in mammalian neurons and is sensitive to both 4-aminopyridine and tetraethylammonium.