Fractional Deletion of Compound Kushen Injection Indicates Cytokine Signaling Pathways are Critical for its Perturbation of the Cell Cycle

We used computational and experimental biology approaches to identify candidate mechanisms of action of aTraditional Chinese Medicine, Compound Kushen Injection (CKI), in a breast cancer cell line (MDA-MB-231). Because CKI is a complex mixture of plant secondary metabolites, we used a high-performance liquid chromatography (HPLC) fractionation and reconstitution approach to define chemical fractions required for CKI to induce apoptosis. The initial fractionation separated major from minor compounds, and it showed that major compounds accounted for little of the activity of CKI. Furthermore, removal of no single major compound altered the effect of CKI on cell viability and apoptosis. However, simultaneous removal of two major compounds identified oxymatrine and oxysophocarpine as critical with respect to CKI activity. Transcriptome analysis was used to correlate compound removal with gene expression and phenotype data. Many compounds in CKI are required to trigger apoptosis but significant modulation of its activity is conferred by a small number of compounds. In conclusion, CKI may be typical of many plant based extracts that contain many compounds in that no single compound is responsible for all of the bioactivity of the mixture and that many compounds interact in a complex fashion to influence a network containing many targets.

Fluid-percussion brain injury induces changes in aquaporin channel expression

Edema, the accumulation of excess fluid, is a major pathological change in the brain that contributes significantly to pathology and mortality after moderate to severe brain injury. Edema is regulated by aquaporin (AQP) channels which transport water across cellular membranes. Six AQPs are found in the brain (1, 3, 4, 5, 8, and 9), and previous studies have found that AQP4 is regulated after traumatic brain injury (TBI). To further understand how AQPs contribute to brain edema, we investigated whether expression of AQP1, 3, and 9 are also regulated after TBI. Adult male Sprague Dawley rats received moderate parasagittal fluid-percussion brain injury (FPI) or sham surgery. After induction of FPI, the injured, ipsilateral parietal cortex and hippocampus were dissected and analyzed by Western blotting. We observed a small decrease in AQP3 and 4 levels at 7 days after FPI in the ipsilateral, parietal cortex. Both AQP1 and 9 significantly increased within 30 min post-injury and remained elevated for up to 6 h in the ipsilateral, parietal cortex. Aqp1 and 9 mRNA levels were also significantly increased at 30 min post-FPI. Administration of an AQP1 and 4 antagonist, AqB013, non-significantly increased brain water content in sham, non-injured animals, and did not prevent edema formation 24 h after trauma in either the parietal cortex or hippocampus. These results indicate that Aqp1 and 9 mRNA and protein levels increase after moderate parasagittal FPI and that an inhibitor of AQP1 and 4 does not decrease edema after moderate parasagittal FPI.

Role of aquaporin-1 in trabecular meshwork cell homeostasis during mechanical strain

Aquaporin-1 (AQP1) channels are expressed by trabecular meshwork (TM) and Schlemm's canal cells of the conventional outflow pathway where fluid movement is predominantly paracellular, suggesting a non-canonical role for AQP1. We hypothesized that AQP1 functions to protect TM cells during periods of mechanical strain. To test this idea, primary cultures of confluent human TM cells on Bioflex membranes were exposed to static and cyclic stretch for 8 and 24h using the Flexcell system. AQP1 expression in TM cells was assessed by SDS-PAGE and Western blot using anti-AQP1 IgGs. AQP1 protein bands were analyzed using densitometry and normalized to beta-actin expression. Cell damage was monitored by measuring lactate dehydrogenase (LDH) and histone deacetylase appearance in conditioned media. Recombinant expression of AQP1 in TM cell cultures was facilitated by transduction with adenovirus. Results show that AQP1 expression significantly increased 2-fold with 10% static stretch and 3.5-fold with 20% static stretch at 8h (n=4, p<0.05) and 24h (n=6, p<0.05). While histone deacetylase levels were unaffected by treatments, release of LDH from TM cells was the most profound at the 20% static stretch level (n=4, p<0.05). Significantly, cells were refractory to the 20% static stretch level when AQP1 expression was increased to near tissue levels. Analysis of LDH release with respect to AQP1 expression revealed an inverse linear relationship (r(2)=0.7780). Taken together, AQP1 in human TM appears to serve a protective role by facilitating improved cell viability during conditions of mechanical strain.

Developmental regulation of the A-type potassium-channel current in hippocampal neurons: role of the Kvbeta 1.1 subunit

The rapidly inactivating A-type K+ current (IA) is prominent in hippocampal neurons; and the speed of its inactivation may regulate electrical excitability. The auxiliary K+ channel subunit Kvbeta 1.1 confers fast inactivation to Shaker-related channels and is postulated to affect IA. Whole-cell patch clamp recordings of rat hippocampal pyramidal neurons in primary culture showed a developmental decrease in the time constant of inactivation (tau(in)) of voltage-gated K+ currents: 17.9+/-1.5 ms in young neurons (5-7 days in vitro; n=53, mean+/-S.E.M.); 9.9+/-1.0 ms in mature neurons (12-15 days in vitro; n=72, mean+/-S.E.M., P<0.01). During the same developmental time, the level of Kvbeta 1.1 transcript increased more than two-fold in vitro and in vivo, determined by semi-quantitative reverse transcriptase-polymerase chain reaction for hippocampus. The hypothesis that up-regulation of Kvbeta 1.1 led to the changes in tau(in) was tested in vitro, using antisense knockdown. Kvbeta 1.1-specific antisense DNA was introduced with a modified herpes virus co-expressing enhanced green fluorescent protein and knockdown of Kvbeta 1.1 was verified by immunocytochemistry. Following transduction with the antisense virus, mature neurons reverted to tau(in) values characteristic of young neurons: 18.3+/-2.4 ms (n=20). The effect of antisense knockdown on electrical excitability was tested using current-clamp protocols to induce repetitive firing. Treatment with the antisense virus increased the interspike interval over a range of membrane depolarization (baseline membrane potential=-40 to +20 mV). This effect was most pronounced at -40 mV, where the ISI of the first pair of action potentials was nearly doubled. These data indicate that Kvbeta 1.1 contributes to the developmental control of IA in hippocampal neurons and that the magnitude of effect is sufficient to regulate electrical excitability. Viral-mediated antisense knockdown of Kvbeta 1.1 is capable of decreasing the electrical excitability of post-mitotic hippocampal neurons, suggesting this approach has applicability to gene therapy of neurological diseases associated with hyperexcitability.

Distinct mechanisms of block of Kv1.5 channels by tertiary and quaternary amine clofilium compounds

The quaternary ammonium compound clofilium and its tertiary amine derivative LY97241 were used to analyze mechanisms of block in a voltage-gated potassium channel. Wild-type and mutant Kv1.5 channels expressed in Xenopus oocytes were recorded by two-electrode voltage clamp. Open-channel block to 20% of the control current amplitude was induced reversibly by 50 microM clofilium or 200 microM LY97241, and was seen as an acceleration of the macroscopic current decay. Although blockers remained present after application, channels recovered from block during each interpulse interval. The optimum voltage for recovery (-45 mV at pH 7.3) at the threshold for channel activation indicated that clofilium block and recovery occurred principally through the open channel state. In contrast, LY97241 appeared to exit from the closed state and the open state. In an acid-tolerant Kv1.5 mutant channel (H452Q), external pH was used to titrate LY97241. At low pH, which protonates the LY97241 amine group, recovery from block at hyperpolarized potentials was impaired in a manner similar to that seen with clofilium. Recovery from clofilium block was reduced at negative potentials independent of pH, an effect attributed to trapping of the permanently charged compound within the closed channels.

Viral vector-mediated expression of K+ channels regulates electrical excitability in skeletal muscle

Modification of K+ currents by exogenous gene expression may lead to therapeutic interventions in skeletal muscle diseases characterized by alterations in electrical excitability. In order to study the specific effects of increasing outward K+ currents, we expressed a modified voltage-dependent K+ channel in primary cultured rat skeletal muscle cells. The rat Kv1.4 channel was expressed as an N-terminal fusion protein containing a bioluminescent marker (green fluorescent protein). Transgene expression was carried out using the helper-dependent herpes simplex 1 amplicon system. Transduced myoballs, identified using fluorescein optics and studied electrophysiologically with single-cell patch clamp, exhibited a greater than two-fold increase in K+ conductance by 20-30 h after infection. This increase in K+ current led to a decrease in membrane resistance and a 10-fold increase in the current threshold for action potential generation. Electrical hyperexcitability induced by the Na+ channel toxin anemone toxin II (1 microM) was effectively counteracted by overexpression of Kv1.4 at 30-32 h after transduction. Thus, virally induced overexpression of a voltage-gated K+ channel in skeletal muscle has a powerful effect in reducing electrical excitability.

Inhibition of aquaporin-1 water permeability by tetraethylammonium: involvement of the loop E pore region

Previously, the only known blockers of water permeability through aquaporin-1 (AQP1) water channels were mercurial reagents such as HgCl(2). For AQP1, inhibition by mercury has been attributed to the formation of a mercaptide bond with cysteine residue 189 found in the putative pore-forming region loop E. Here we show that the nonmercurial compound, tetraethylammonium (TEA) chloride, reduces the water permeability of human AQP1 channels expressed in Xenopus oocytes. After preincubation of the oocytes for 15 min with 100 microM TEA, AQP1 water permeability was reduced by 20 to 40%, a degree of partial block similar to that obtained with 15 min of incubation in 100 microM HgCl(2). The reduction of water permeability was dose-dependent for tested concentrations up to 10 mM TEA. TEA blocks the Shaker potassium channel by interacting with a tyrosine residue in the outer pore region. We tested whether an analogous tyrosine residue in loop E of AQP1 could be involved in the binding of TEA. Using polymerase chain reaction, tyrosine 186 in AQP1, selected for its proximity to the mercury-binding site, was mutated to phenylalanine (Y186F), alanine (Y186A), or asparagine (Y186N). Oocyte expression of the mutant AQP1 channels showed that the water permeability of Y186F was equivalent to that of wild-type AQP1; the other mutant channels did not conduct water. However, in contrast to wild-type AQP1, the water permeability of Y186F was not reduced with 100 microM TEA. These results suggest that TEA reduces AQP1 water permeability by interacting with loop E.

Antisense knockdown of calcium-dependent K+ channels in developing cerebellar Purkinje neurons

Normal developmental upregulation of K(Ca) channel activity in cultured rat cerebellar Purkinje neurons was selectively inhibited by antisense oligonucleotide sequence (3 microM) targeted against the rslo transcript. The knockdown was specific; delayed rectifier and apamin-sensitive K+ channel abundances in Purkinje neurons were not affected by rslo antisense. Sense oligonucleotides (3 microM), used as a control, had no effect on channel abundance. Quantitative morphometric analyses of anti-calbindin-labeled Purkinje neurons showed no differences between neurons in control, sense and antisense treatment groups, and confirmed that the presence of the added oligonucleotide in the sense and antisense treatment conditions had no discernable toxic effects on neuronal health, for which neurite outgrowth is a sensitive indicator. These results confirm the identification of the developmentally regulated K(Ca) channel as the product of the gene rslo in cerebellar Purkinje neurons.

Cloned human aquaporin-1 is a cyclic GMP-gated ion channel

Aquaporin-1 (AQP1) is a member of the membrane intrinsic protein (MIP) gene family and is known to provide pathways for water flux across cell membranes. We show here that cloned human AQP1 not only mediates water flux but also serves as a cGMP-gated ion channel. Two-electrode voltage-clamp analyses showed consistent activation of an ionic conductance in wild-type AQP1-expressing oocytes after the direct injection of cGMP (50 nl of 100 mM). Current activation was not observed in control (water-injected) oocytes or in AQP5-expressing oocytes with osmotic water permeabilities equivalent to those seen with AQP1. Patch-clamp recordings revealed large conductance channels (150 pS in K(+) saline) in excised patches from AQP1-expressing oocytes after the application of cGMP to the internal side. Amino acid sequence alignments between AQP1 and sensory cyclic-nucleotide-gated channels showed similarities between the cyclic-nucleotide-gated binding domain and the AQP1 carboxyl terminus that were not present in AQP5. Competitive radioligand-binding assays with [(3)H]cGMP demonstrated specific binding (K(D) = 0.2 microM) in AQP1-expressing Sf9 cells but not in controls. These results indicate that AQP1 channels have the capacity to participate in ionic signaling after the activation of cGMP second-messenger pathways.

Expression of Niemann-Pick type C transcript in rodent cerebellum in vivo and in vitro

This study assesses the developmental expression of the Niemann-Pick type C mRNA in vivo and in vitro in rat cerebellum. NPC is an autosomal recessive neurovisceral lipid storage disease associated with an alteration in cholesterol trafficking. In the mouse model of NPC and in the early onset form of human NPC, Purkinje neurons are among the first neurological targets, suffering stunted growth during postnatal development and dying, leading to ataxia. Recently, the genes responsible for human (NPC1) and mouse (Npc1) NPC disease have been cloned. Based on a highly homologous domain, we designed primers to look for levels of Npc1 mRNA with a semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) approach using cyclophilin as an internal standard. Total RNA was isolated from various postnatal developmental stages of the rat cerebellum as template for the analyses. Npc1 transcripts were observed at postnatal day 0 and at later stages of development, both in vivo and in vitro from primary cerebellar cultures. To identify the location of Npc1 inside the cerebellum, we performed immunostaining with an anti-Npc1 antibody in primary rat cerebellar cultures identifying reactive Purkinje neurons by double-labeling with the Purkinje specific marker calbindin and sub-populations of glial cells. In summary, Npc1 is expressed in rat cerebellum in vivo and in vitro and is expressed during early postnatal development as well as in the adult cerebellum. Since Npc1 is expressed at similar levels throughout development, the vulnerability of Purkinje neurons to this disease is likely to involve disruption of an interaction with other developmentally-regulated proteins.

Differential expression of three classes of voltage-gated Ca(2+) channels during maturation of the rat cerebellum in vitro

Voltage-gated Ca(2+) channels provide a mode of Ca(2+) influx that is essential for intracellular signaling in many cells. Semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) was used to assess the relative amounts of mRNAs encoding three classes of Ca(2+) channels (alpha1A, alpha1B and alpha1E) during development, in cultures established from prenatal rat cerebellar cortex. Ca(2+) channel transcript levels were standardized to a constitutive marker (cyclophilin). For all three classes of Ca(2+) channels, transcript levels were highest at early stages (4-10 days in vitro) and declined with age. This developmental pattern was differentially regulated by a depolarizing agent, tetraethylammonium chloride (TEA, 1 mM). Chronic depolarization yielded a significant elevation in transcript levels for alpha1B (N-type) and alpha1E (R-type) Ca(2+) channels during neuronal maturation (10-21 days in vitro), but dramatically suppressed transcript levels for the alpha1A (P-type) Ca(2+) channel at all stages of development. The effects of TEA on alpha1A, alpha1B and alpha1E transcript levels were mimicked by increasing external K(+) (from 5 to 10 mM). The regulatory effects of depolarization on transcript levels were dependent on extracellular Ca(2+) for alpha1E but not for alpha1A. For alpha1B, transcript levels depended on extracellular Ca(2+) only for increased K(+) as the depolarizing stimulus, but not for TEA. These results suggest that levels of Ca(2+) channel transcripts in rat cerebellum are developmentally regulated in vitro and can be influenced differentially by transmembrane signaling via chronic depolarization and Ca(2+) entry. Dynamic regulation of Ca(2+) channel expression may be relevant to the different functional roles of Ca(2+) channels and their regional localization within neurons.

Differential sensitivity of voltage-gated potassium channels Kv1.5 and Kv1.2 to acidic pH and molecular identification of pH sensor

Kv1.2 and Kv1.5 are two subtypes of voltage-gated potassium channels expressed in heart that are thought to contribute to phase 1 (ITO) and phase 3 (IK) components of cardiac action potential repolarization. Although the effect of decreased pH in prolonging cardiac action potentials is well documented, the molecular target of acidification has not previously been determined. We expressed Kv1.2 and Kv1.5 in Xenopus oocytes to study the effect of acidic and alkaline extracellular pH on channel function. Using two-electrode voltage clamp and cellattached patch clamp, we demonstrate that Kv1. 5 channels show enhanced C-type inactivation at acidic pH that is relevant to pathophysiological conditions. In contrast, homologous Kv1.2 channels are resistant to acidic pH. Both channel types are insensitive to alkaline pH. A histidine residue in the third extracellular loop of Kv1.5 (H452) accounts for the difference in pH sensitivity between the Kv1.5 and Kv1.2 channels. Mutation of histidine H452 to a glutamine residue in Kv1.5 yields a channel that no longer shows enhanced inactivation with acidification. These data provide insight into mechanisms subserving known pH effects on cellular signaling functions. Our results demonstrate that H452 in the third extracellular loop of Kv1.5 plays a role in C-type inactivation, thus expanding the known complement of protein regions that contribute to the slow K+ channel inactivation mechanism.

Increased calcium-dependent K+ channel activity contributes to the maturation of cellular firing patterns in developing cerebellar Purkinje neurons

Developmental changes in neuronal excitability reflect the regulated expression of ion channels and receptors. Purkinje neurons of the rat cerebellum progress from slow irregular firing to a fast pacemaker-like pattern during postnatal development in vivo. In this study, a comparable period of development in culture was investigated at the protein level using cell-attached single channel recordings to quantify the abundance of active calcium-dependent (KCa) and delayed rectifier (KD) potassium channels. In control cultures, KCa channel activity increased whereas KD channel activity was not significantly different with developmental age. The increase in active KCa channels was antagonized by chronic treatment with the blocker, tetraethylammonium (TEA, 1 mM), which also retarded the normal development of cellular firing patterns. The consequences of chronic TEA treatment were assessed in cultures after thorough washout of the TEA-containing culture medium. Current clamp analyses (nystatin-perforated patches) showed that control Purkinje neurons progressed from a single spike mode to a repetitive firing mode, with a concomitant decrease in action potential duration and an increase in maximal firing rate. Chronic TEA treatment prevented these changes; Purkinje neurons retained the slow firing rate and long duration action potentials that are typical of the immature state. These data suggest that the developmental increase in KCa channel activity may be required for the maturation of cellular firing patterns in cerebellar Purkinje neurons.

Morphological consequences of altered calcium-dependent transmembrane signaling on the development of cultured cerebellar Purkinje neurons

Morphometric analyses of cultured rat Purkinje neurons, visualized with anti-calbindin, demonstrated that elevated KCl (10 mM) significantly increased dendritic outgrowth and branching. The response was blocked by NiCl2 (50 microM; R-type Ca2+ channel antagonist). Cells grown in low external Ca2+ (100 nM) showed no loss of responsiveness to elevated potassium. However, thapsigargin (1 microM; Ca(2+)-ATPase blocker) inhibited dendrite outgrowth, suggesting that intracellular calcium stores may be important in governing development.

Regulation of Ca2+-dependent K+ channel expression in rat cerebellum during postnatal development

Potassium channels govern duration and frequency of excitable membrane events and may regulate signals that are important in neuronal development. This study assesses the developmental expression of the large conductance Ca2+-dependent K+ channel in vivo and in vitro in rat cerebellum. In vivo, transcript levels for the Ca2+-dependent K+ channel (KCa) were shown by Northern analysis to increase during development, whereas transcript levels for the voltage-gated K+ channel Kv3.1, a delayed rectifier (KD), remained relatively constant. A comparable pattern was demonstrated by expression in Xenopus oocytes of poly(A)-enriched RNA isolated from postnatal rat cerebella. In cerebellar cultures, increased external K+ provided a simple manipulation of cell excitability that influenced KCa transcript levels during development. With low external K+ (5.3 mM), the levels of KCa channel transcript (assessed by semiquantitative PCR) remained constant throughout development. However, in culture medium that supported significant dendritic outgrowth (10 mM extracellular K+), an upregulation of KCa transcript level was observed similar to that seen in vivo. Tetraethylammonium (TEA; 1 mM) similarly enhanced KCa expression, suggesting that depolarizing stimuli increased KCa expression. The stimulatory effects of increased K+ or TEA on KCa expression required extracellular Ca2+ and were abolished in low external calcium (0.1 mM, buffered with EGTA), although morphological development and survival were not impaired. The regulation of KCa channel expression by depolarization and Ca2+ entry provides evidence of a logical feedback mechanism governing Ca2+ signals that may be significant in cerebellar development.

Anomalous mole fraction effect induced by mutation of the H5 pore region in the Shaker K+ channel

Mutagenesis of the H5 region of the Shaker K+ channel has provided strong evidence that these amino acids form a major portion of the ionic pore. We have previously observed that a single-site mutation (T441S) in this region increased the apparent relative permeability of the channel to NH4+. We now report that this increased relative permeability to NH4+ is sensitive to small changes in external K+ in a pattern consistent with an anomalous mole fraction effect. The effect is not apparent in the wild-type channel. These findings, in combination with other studies showing effects of this particular mutation on the binding of tetraethylammonium and hydroxylamine, support the hypothesis that T441S alters the affinity of a putative ion binding site for NH4+ and ammonium derivatives. The mutation T441S alters ionic selectivity and reveals the multi-ion nature of the mutant Shaker K+ channel.

Forskolin stimulation of water and cation permeability in aquaporin 1 water channels

Aquaporin 1, a six-transmembrane domain protein, is a water channel present in many fluid-secreting and -absorbing cells. In Xenopus oocytes injected with aquaporin 1 complementary RNA, the application of forskolin or cyclic 8-bromo- adenosine 3',5'-monophosphate increased membrane permeability to water and triggered a cationic conductance. The cationic conductance was also induced by direct injection of protein kinase A (PKA) catalytic subunit, reduced by the kinase inhibitor H7, and blocked by HgCl2, an inhibitor of aquaporin 1. The cationic permeability of the aquaporin 1 channel is activated by a cyclic adenosine monophosphate-dependent mechanism that may involve direct or indirect phosphorylation by PKA.

Cloning of a receptor for prostaglandin F2 alpha from the ovine corpus luteum

A complementary DNA clone encoding a functional receptor for prostaglandin F2 alpha (PGF2 alpha) has been isolated from an ovine large luteal cell complementary DNA library (prepared from day 10 mid-luteal phase RNA). This receptor, which has been designated FP, consists of 362 amino acids (M(r) = 40,982) and is a member of the family of G protein-coupled receptors. Radioligand binding studies with membranes prepared from transfected COS cells demonstrated specific 17-[3H]phenyl-trinor-PGF2 alpha binding that was displaced by prostanoids in the order of 17-phenyl-trinor-PGF2 alpha > PGF2 alpha > fluprostenol > PGD2 > PGE2 >> 8-epi PGF2 alpha. Xenopus laevis oocytes injected with RNA encoding the ovine FP receptor responded to 17-phenyl-trinor-PGF2 alpha with increased membrane chloride conductance in calcium-free medium. Northern blot analysis with RNA from day 10 corpus luteum showed a major band of approximately 6.1 kilobases. On day 14, when luteolysis usually starts, the abundance of this 6.1-kilobase band was variable between individual ewes, and on day 16, when luteolysis is underway, the message was uniformly less abundant. This variability appeared to correlate with circulating progesterone. Thus, when the progesterone level was high (days 10 and 14 depending on whether luteolysis had started), the amount of FP receptor message was high, whereas when the progesterone level was low or falling (day 16), the amount of FP receptor message decreased. We have cloned an ovine FP receptor whose expression confers appropriate functional activity in COS cells and Xenopus oocytes. Furthermore, the level of messenger RNA encoding the FP receptor is high in the midluteal phase ovine corpus luteum and decreases during luteolysis.

Interactions of the H5 pore region and hydroxylamine with N-type inactivation in the Shaker K+ channel

Mutations at sites in the H5 region of the Shaker B K+ channel were used to analyze the influence of the pore on N-type inactivation. Single-channel and two-electrode voltage clamp analyses showed that mutations at residues T441 and T442, which are thought to lie at the internal mouth of the pore, produced opposite effects on inactivation: the inactivated state is stabilized by T441S and destabilized by T442S. In addition, an ammonium derivative, hydroxylamine (OH-(NH3)+), appears to bind in the pore region of T441S and further decreases the rate of recovery from N-type inactivation. This effect relies on the presence of the amino-terminal. The effect of hydroxylamine on the T441S mutation of this K+ channel shows several properties analogous to those of local anesthetics on the Na+ channel. These results can be interpreted to suggest that part of the H5 region contributes to the receptor for the inactivation particle and that a hydroxylamine ion trapped near that site can stabilize their interaction.

Block of the inactivating potassium channel by clofilium and hydroxylamine depends on the sequence of the pore region

Cardiac antiarrhythmic compounds are a diverse group divided into classes that differ in their mechanisms of action. Recent attention has focused on class III compounds, which prolong the action potential by blocking K+ channels. The purpose of this study was to characterize the mechanisms of actions of a class III compound, clofilium, and a simple analog, hydroxylamine, on an inactivating K+ channel. The defined system used a cloned inactivating K+ channel (Shaker-B) expressed in Xenopus oocytes. This channel is similar in physiological properties and core sequence to the inactivating K+ channel cloned from mammalian heart. Results presented here demonstrate that clofilium (100 microM) and hydroxylamine (10 mM) can cause use-dependent block, depending on the sequence of the pore region. A mutation of the pore known to influence selectivity and tetraethylammonium binding (threonine-441 to serine) confers use-dependent sensitivity to hydroxylamine and clofilium. Hybrid channels were formed from the coinjection of wild-type and mutant channel mRNAs; the analysis of block with the hybrid channels suggests that binding of hydroxylamine involves all subunits of the tetrameric channel, whereas clofilium affects channels containing as few as one mutant subunit. The simplest interpretation is that all four subunits contribute to an internal binding site for blockers such as clofilium and hydroxylamine and threonine-441 influences this binding site. The effectiveness of clofilium, unlike hydroxylamine, on the hybrid channels may reflect its structural complexity, which could allow interaction with a broader receptor site. Future studies will test this idea using other class III-related compounds.

Developmental changes in calcium conductances contribute to the physiological maturation of cerebellar Purkinje neurons in culture

The relationship between calcium conductances and developmental changes in the active and passive membrane properties of cerebellar Purkinje neurons from rats was studied in a culture model system by using current-clamp and voltage-clamp techniques. These cultures, at 6-21 d of age, represented the main period of morphological and physiological development of the Purkinje neuron. In the current-clamp studies, input resistance decreased and the current-voltage curve became more S-shaped as the neurons matured in culture. Spike-generating properties also changed. Immature Purkinje neurons without dendritic structure produced repetitive, fast TTX-sensitive simple spikes when stimulated electrically. The simple spike frequency increased with maturation. In older neurons (greater than or equal to 12 d in vitro) with well-developed dendritic structure, a burst event, the complex spike, preceded the repetitive simple spike firing. Magnesium (10 mM) and cadmium (50-100 microM), calcium channel blockers, antagonized the repetitive simple spike firing in both young and old neurons. The complex spike of the older neurons was also antagonized by magnesium (10 mM) but was resistant to cadmium (50-100 microM), suggesting that a pharmacologically distinct calcium conductance mediated this spike event. Whole-cell voltage-clamp recordings showed that the older Purkinje neurons expressed two calcium currents, a low-threshold rapidly inactivating calcium current resistant to cadmium (50-100 microM) and a high-threshold slowly inactivating calcium current antagonized by cadmium (50-100 microM). In young Purkinje neurons without dendritic structure (6-9 d in vitro), only the high-threshold calcium current was evident. The amplitude of this current increased approximately 50% during development. These results indicate that the developmental expression of calcium conductances plays a prominent role in the physiological maturation of the cultured Purkinje neurons, which closely simulate the physiologic cells they model. The high-threshold calcium conductance is expressed early in development and contributes to repetitive simple spike firing of both the young and old neurons. The low-threshold calcium conductance appears later in development, coincident with dendritic expression, and plays a major role in the generation of the complex spike.

Multiple ionic mechanisms are activated by the potent agonist quisqualate in cultured cerebellar Purkinje neurons

Current clamp recordings were used to analyze responses of cultured cerebellar Purkinje neurons to quisqualate and several other selective non-N-methyl- D-aspertate (NMDA) agonists. Quisqualate, a potent agonist in the cerebellar Purkinje neuron, evoked both short- and long-term changes in excitability, that activated within seconds and lasted for several minutes. Two components of the response were activated differentially by subtype selective agonists, and differed in their mechanism of expression and time course. The initial component of the response was activated by ionotropic agonists ((RS)-d-amino-3-hydroxyl-5-methyl-4-isoxazolepropionic acid (AMPA) domoate), and by quisqualate and glutamate which are effective at both the ionotropic and metabotropic quisqualate receptor subtypes, but not by the metabotropic agonist trans (+/-)-1-amino-1,3-cyclopentanedicarboxylic acid (ACPD). This component was dependent on extracellular Na+, and characterized by a rapid depolarization with a short latency (less than 1-2 s) and a decrease in membrane resistance as expected for an ionotropic reponse. The rapid depolarization extended into an agonist-dependent plateau phase, which could not be evoked by depolarization alone. The second ('late') phase of the response was a slowly-activating, long-lasting change in membrane excitability, accompanied by little or no change in the membrane potential. The late phase, marked by an increase in voltage-dependent bursting spike activity, was induced by the metabotropic agonist, ACPD, and by quisqualate and glutamate, but not by ionotropic selective agonists such as AMPA. Little or no bursting was evoked by AMPA, domoate, kainate or homocysteate. This late phase was also accompanied by increases in the magnitude and duration of the complex spikes and in the afterhyperpolarization following brief current-driven depolarizations. The slower time course of the late component is consistent with a pathway involving second messenger systems. Our results support the hypothesis that coregulation of both ionotropic and metabotropic mechanisms produces the complex and prolonged excitatory response characteristic of the Purkinje neuron.

Single-channel K+ currents recorded from the somatic and dendritic regions of cerebellar Purkinje neurons in culture

Voltage-sensitive K+ channels were studied in rat cerebellar Purkinje neurons in culture using the single-channel recording technique. Recordings in the cell-attached and outside-out configuration revealed multiple voltage-sensitive K+ channel types in patches from both the somatic and the dendritic regions. K+ channel types were present in all patches studied. The same channel types were observed in somatic and dendritic recordings. Channel types were identified by reversal potential, single-channel conductance, voltage sensitivity, and patterns of activity. In cell-attached patches recorded under physiological conditions, 3 channel types were identified. Mean single-channel conductances were 92, 57, and 12 pS. All 3 channel types were activated by membrane depolarization. Similar channel types were identified in inside-out and outside-out patches recorded under physiological conditions. Two additional channel types were identified in the outside-out patches, with mean single-channel conductances of 41 and 26 pS. In cell-attached recordings under symmetrical K+ conditions, 6 channel types were identified. Mean single-channel conductances were 222, 134, 39, 25, 14, and 15 pS. Channel types with mean conductances of 222, 134, and 39 pS required membrane depolarization for activation. A comparison of channel properties indicated that these channel types correlated with the 3 channel types observed in cell-attached patches under physiological conditions. The 3 smaller-conductance channel types (25, 14, and 15 pS) were active at potentials around rest or at hyperpolarized membrane potentials. Two K+ channel types (39 and 25 pS) were commonly associated with the late phase of extracellularly recorded spontaneous spike events, suggesting a functional role in the repolarizing phase of somatic and dendritic action potentials. These results demonstrate that voltage-sensitive K+ channels are a prominent component of both the somatic and the dendritic membrane of the cerebellar Purkinje neuron and support the view that multiple voltage-sensitive K+ channel types contribute to the membrane functions of both cellular regions in this CNS neuronal type.

Alteration of ionic selectivity of a K+ channel by mutation of the H5 region

The high ionic selectivity of K+ channels is a unifying feature of this diverse class of membrane proteins. Though K+ channels differ widely in regulation and kinetics, physiological studies have suggested a common structure: a single file pore containing multiple ion-binding sites and having broader vestibules at both ends. We have used site-directed mutagenesis and single-channel recordings to identify a molecular region that influences ionic selectivity in a cloned A-type K+ channel from Drosophila. Single amino-acid substitutions in H5, the fifth hydrophobic region, enhanced the passage of NH4+ and Rb+, ions with diameters larger than K+, without compromising the ability of the channel to exclude the smaller cation, Na+. The mutations that substantially altered selectivity had little effect on the gating properties of the channel. We conclude that the H5 region is likely to line the pore of the K+ channel.

Unique properties of non-N-methyl-D-aspartate excitatory responses in cultured purkinje neurons

Cerebellar Purkinje neurons respond to glutamate and to the agonists quisqualate (QA) and kainate (KA) with prolonged, multiphasic, voltage-dependent depolarizations. In contrast, N-methyl-D-aspartate (NMDA) at equivalent doses is not effective as an agonist for Purkinje neurons. The responses to QA and KA are reduced by extracellular Cd2+ (30 microM), by increased Mg2+ or Ca2+ (12 mM), and by the glutamate antagonist kynurenic acid (1 mM) but not by the NMDA-selective antagonist 2-amino-5-phosphonovalerate (100 microM). The short pressure application of 1 microM QA (less than or equal to 0.5 s) produces a response often exceeding 1 min in duration, which consists of several phases: rapid initial depolarization, followed by a long plateau, repolarization, and a subsequent small hyperpolarization. A similar response is evoked by glutamate and KA at higher doses (30-50 microM). The initial and plateau depolarizations are dependent on Na+, being reduced by substitution of external Na+ with sucrose or choline, but are not affected by the Na+ channel blocker tetrodotoxin. Rectification, observed at hyperpolarized potentials below -60 mV set by current clamp, is attributed in part to an intrinsic voltage sensitivity of the agonist-activated response. Both the duration and the magnitude of the excitatory responses were found to be voltage-dependent. Single-channel recordings of a Ca2+-sensitive K+ channel, activated selectively during the excitatory response, suggest that intracellular Ca2+ increases during the plateau phase. Certain properties of the excitatory responses in the Purkinje neuron resemble those associated with NMDA-receptor activation in other regions of the central nervous system, including voltage-sensitive rectification, blockade by divalent cations, and the induction of increased intracellular Ca2+ during the excitatory response. These unique properties may enable the Purkinje neuron to express both rapid and long-term effects of glutamatergic transmission with non-NMDA receptors alone.

Multiple voltage-sensitive K+ channels regulate dendritic excitability in cerebellar Purkinje neurons

Ionic conductances present in the dendritic region of the cerebellar Purkinje neuron were studied using the single-channel and whole-cell recording methods. Several types of voltage-sensitive K+ channels including a Ca2+ activated K+ channel were found to be a prominent components of the dendritic membrane. All patches studied contained K+ channel types and most patches contained more than one K+ channel type. In cell attached recordings, K+ channel activity was associated with the late phase of spontaneous action potentials suggesting a functional relationship. These data demonstrate that voltage-sensitive ion channels contribute to dendritic excitability and suggest that the transduction and integration of synaptic signals may involve both active and passive ionic conductances.

Developmental changes in K+-selective channel activity during differentiation of the Purkinje neuron in culture

The cerebellar Purkinje neuron cultured from 20 d rat embryos is electrically inexcitable when immature, and acquires excitable membrane properties according to a programmed developmental sequence, thus providing a useful model for investigating mechanisms of CNS neuronal development. Using conventional patch-clamp techniques, we have characterized the the predominant classes of active K+-selective channels at a range of ages encompassing the entire developmental process from 5 to 29 d in vitro (DIV), and have shown pharmacologically that these channels are important contributors to the patterns of spontaneous activity generated by the Purkinje neurons. The 4 predominant classes of K+ channels that are active during steady-state depolarizing voltage commands are identified by unit conductances as the 27, 44, 70, and 100 pS channels, and show differences in several properties, including voltage dependence, sensitivity to tetraethylammonium chloride (TEA), mean open time, and time of appearance during development. Intracellular current-clamp recordings show that physiological maturation of the Purkinje neuron entails increases in the firing rate, the diversity of spike events that comprise spontaneous activity, and the sensitivity of spontaneous activity to disruption by the K+ channel blocker TEA. This increase in sensitivity to TEA correlates with the new expression of activity of the larger-conductance TEA-sensitive classes of K+ channel (70 and 100 pS types). These data show that developmental regulation of the activity of K+-selective channels contributes significantly to the ionic mechanisms that underlie the developmental transitions in spontaneous activity patterns in the Purkinje neuron.

Development of spontaneous and glutamate-evoked activity is altered by chronic ethanol in cultured cerebellar Purkinje neurons

The effects of continuous exposure to ethanol on the cytological and physiological development of a central nervous system (CNS) neuron were studied using the cultured Purkinje neuron of the rat cerebellar cortex. Purkinje neurons in fetal rat brain cultures which are established at one day before birth show development comparable to that described in vivo in other studies. In culture, Purkinje neurons progress from immature rounded cells with fine neurites to mature neurons with a branched dendritic structure. These structural changes are accompanied by an increase in the duration and complexity of the excitatory response to glutamate, by transitions in the patterns of spontaneous activity, and by an increase in mean firing rate. Our results demonstrate that chronic exposure to a low concentration of ethanol (90 mg%; 19.5 mM) during development selectively alters the electrophysiological but not the morphological properties of Purkinje neurons. Specifically, ethanol treatment reduces the responsiveness of these neurons to glutamate, delays the expected developmental transitions in patterns of spontaneous activity, and induces increased spontaneous bursting activity, particularly at the stage of dendritic formation. Impairment of responsiveness to glutamate is significant in that it may reflect the compromise by ethanol of a major excitatory pathway in the cerebellar cortex, resulting from the decreased efficacy of glutamatergic input from parallel fibers. In contrast to the results of other studies using adult neurons as a model for the effects of ethanol, our work suggests that the developing CNS neuron does not become tolerant; that is, in the continuing presence of ethanol, it does not express physiological function equivalent to that of the control.