The molecular biology of K+ channels.

It is now clear that voltage-gated K+ channels are encoded by a set of multigene subfamilies. Expression of different members of these subfamilies, coupled with mutational analysis, has advanced our knowledge of the structure and function of voltage-dependent K+ channels.

Exocytotic insertion of calcium channels constrains compensatory endocytosis to sites of exocytosis.

Proteins inserted into the cell surface by exocytosis are thought to be retrieved by compensatory endocytosis, suggesting that retrieval requires granule proteins. In sea urchin eggs, calcium influx through P-type calcium channels is required for retrieval, and the large size of sea urchin secretory granules permits the direct observation of retrieval. Here we demonstrate that retrieval is limited to sites of prior exocytosis. We tested whether channel distribution can account for the localization of retrieval at exocytotic sites. We find that P-channels reside on secretory granules before fertilization, and are translocated to the egg surface by exocytosis. Our study provides strong evidence that the transitory insertion of P-type calcium channels in the surface membrane plays an obligatory role in the mechanism coupling exocytosis and compensatory endocytosis.

Prolonged activation of mitochondrial conductances during synaptic transmission.

Although ion channels have been detected in mitochondria, scientists have not been able to record ion transport in mitochondria of intact cells. A variation of the patch clamp technique was used to record ion channel activity from intracellular organelles in the presynaptic terminal of the squid. Electron microscopy indicated that mitochondria are numerous in this terminal and are the only organelles compatible with the tips of the pipettes. Before synaptic stimulation, channel activity was infrequent and its conductance was small, although large conductances ( approximately 0.5 to 2.5 nanosiemens) could be detected occasionally. During a train of action potentials, the conductance of the mitochondrial membrane increased up to 60-fold. The conductance increased after a delay of several hundred milliseconds and continued to increase after stimulation had stopped. Recovery occurred over tens of seconds.

Xenopus oocytes injected with rat uterine RNA express very slowly activating potassium currents.

Under the influence of estrogen, uterine smooth muscle becomes highly excitable, generating spontaneous and prolonged bursts of action potentials. In a study of the mechanisms by which this transition in excitability occurs, polyadenylated RNA from the uteri of estrogen-treated rats was injected into Xenopus oocytes. The injected oocytes expressed a novel voltage-dependent potassium current. This current was not observed in oocytes injected with RNA from several other excitable tissues, including rat brain and uterine smooth muscle from ovariectomized rats not treated with estrogen. The activation of this current on depolarization was exceptionally slow, particularly for depolarizations from relatively negative membrane potentials. Such a slowly activating channel may play an important role in the slow, repetitive bursts of action potentials in the myometrium.

A Shab potassium channel contributes to action potential broadening in peptidergic neurons.

We have cloned the gene for a potassium channel, Aplysia Shab, that is expressed in the bag cell neurons of Aplysia. The voltage dependence and kinetics of the Aplysia Shab current in oocytes match those of IK2, one of the two delayed rectifiers in these neurons. Like IK2, but in contrast with other members of the Shab subfamily, the Aplysia Shab current inactivates within several hundred milliseconds. This inactivation occurs by a process whose properties do not match those previously described for C-type and N-type mechanisms. Neither truncation of the N-terminus nor block by tetraethylammonium alters the time course of inactivation. By incorporating the characteristics of Aplysia Shab into a computational model, we have shown how this current contributes to the normal enhancement of action potentials that occurs in the bag cell neurons at the onset of neuropeptide secretion.

Neuropeptide inhibition of voltage-gated calcium channels mediated by mobilization of intracellular calcium.

Many neurotransmitters and hormones regulate secretion from endocrine cells and neurons by modulating voltage-gated Ca2+ channels. One proposed mechanism of neurotransmitter inhibition involves protein kinase C, activated by diacylglycerol, a product of phosphatidyl-inositol inositol hydrolysis. Here we show that thyrotropin-releasing hormone (TRH), a neuropeptide that modulates hormone secretion from pituitary tumor cells, inhibits Ca2+ channels via the other limb of the phosphatidylinositol signaling system: TRH causes inositol trisphosphate-triggered Ca2+ release from intracellular organelles, thus causing Ca2(+)-dependent inactivation of Ca2+ channels. Elevation of intracellular Ca2+ concentration is coincident with the onset of TRH-induced inhibition and is necessary and sufficient for its occurrence. The inhibition is blocked by introducing Ca2+ buffers into cells and mimicked by a variety of agents that mobilize Ca2+. Treatments that suppress protein kinase C have no effect on the inhibition. Hence inactivation of Ca2+ channels occurs not only as a result of Ca2+ influx through plasma membrane channels, but also via neurotransmitter-induced Ca2+ mobilization. This phenomenon may be common but overlooked because of the routine use of Ca2+ buffers in patch-clamp electrodes.

Giga-ohm seals on intracellular membranes: a technique for studying intracellular ion channels in intact cells.

A method is outlined for obtaining giga-ohm seals on intracellular membranes in intact cells. The technique employs a variant of the patch-clamp technique: a concentric electrode arrangement protects an inner patch pipette during penetration of the plasma membrane, after which a seal can be formed on an internal organelle membrane. Using this technique, successful recordings can be obtained with the same frequency as with conventional patch clamping. To localize the position of the pipette within cells, lipophilic fluorescent dyes are included in the pipette solution. These dyes stain the membrane of internal organelles during seal formation and can then be visualized by video-enhanced or confocal imaging. The method can detect channels activated by inositol trisphosphate, as well as other types of intracellular membrane ion channel activity, and should facilitate studies of internal membranes in intact neurons and other cell types.

Recruitment of Ca2+ channels by protein kinase C during rapid formation of putative neuropeptide release sites in isolated Aplysia neurons.

Activation of protein kinase C (PKC) in Aplysia bag cell neurons causes the recruitment of voltage-dependent calcium channels. Using imaging techniques on isolated cells, we have now found that an activator of PKC, 12-O-tetradecanoyl-phorbol-13-acetate (TPA), promotes the rapid appearance of new sites of calcium influx associated with a change in the morphology of neurite endings. In untreated cells, calcium influx triggered by action potentials occurs along neurites and in the central region of growth cones, but does not usually occur at the leading edge of lamellipodia. TPA produces extension of the lamellipodium, and action potentials now trigger calcium influx at the distal edge of the newly extended endings. Cotreatment with TPA and a cyclic AMP analog promotes movement of secretory organelles toward the new sites of calcium influx. Our results suggest that these second messenger systems promote the rapid formation of morphological structures that contribute to the potentiation of peptide release.

Cyclic AMP modulates fast axonal transport in Aplysia bag cell neurons by increasing the probability of single organelle movement.

Stimulation of Aplysia bag cell neurons triggers elevation of cAMP and prolonged secretion of ELH neuropeptide. Using video-enhanced microscopy to track individual organelle movements in bag cell neurons, we find that organelle translocation consists of periods of movement interrupted by stationary episodes. cAMP elevation leads to a 2- to 3-fold enhancement of the average rate of organelle transport in both anterograde and retrograde directions. This effect does not result from alteration of the instantaneous velocity of organelle transport along microtubules, but rather from an increase in the proportion of time individual organelles spend in motion. Biochemical measurements also provided evidence that cAMP elevation promotes ELH peptide translocation from the somata into axons. Enhanced transport of ELH as a result of these effects may contribute to the replenishment of neuropeptide-containing vesicles at release sites during prolonged periods of secretion.

Estrogen induction of a small, putative K+ channel mRNA in rat uterus.

Estrogen causes dramatic long-term changes in the activity of the uterus. Here we report the molecular cloning of a small (700 base) uterine mRNA species capable of inducing a slow K+ current in Xenopus oocytes. The 130 amino acid protein encoded by this mRNA species has a predicted structure that does not resemble that of previously described voltage-dependent channels from mammalian sources. It is, however, similar to structural motifs found in certain prokaryotic ion channels. The induction of this mRNA by estrogen is rapid; this uterine mRNA species is not detectable in uteri from estrogen-deprived rats, but is substantially induced after 3 hr of estrogen treatment. These results support a critical role for regulation of ion channel expression by estrogen in the uterus.

Targeted attenuation of electrical activity in Drosophila using a genetically modified K(+) channel.

We describe here a general technique for the graded inhibition of cellular excitability in vivo. Inhibition is accomplished by expressing a genetically modified Shaker K(+) channel (termed the EKO channel) in targeted cells. Unlike native K(+) channels, the EKO channel strongly shunts depolarizing current: activating at potentials near E(K) and not inactivating. Selective targeting of the channel to neurons, muscles, and photoreceptors in Drosophila using the Gal4-UAS system results in physiological and behavioral effects consistent with attenuated excitability in the targeted cells, often with loss of neuronal function at higher transgene dosages. By permitting the incremental reduction of electrical activity, the EKO technique can be used to address a wide range of questions regarding neuronal function.

Kv1.3 channel gene-targeted deletion produces "Super-Smeller Mice" with altered glomeruli, interacting scaffolding proteins, and biophysics.

Mice with gene-targeted deletion of the Kv1.3 channel were generated to study its role in olfactory function. Potassium currents in olfactory bulb mitral cells from Kv1.3 null mice have slow inactivation kinetics, a modified voltage dependence, and a dampened C-type inactivation and fail to be modulated by activators of receptor tyrosine signaling cascades. Kv1.3 deletion increases expression of scaffolding proteins that normally regulate the channel through protein-protein interactions. Kv1.3-/- mice have a 1,000- to 10,000-fold lower threshold for detection of odors and an increased ability to discriminate between odorants. In accordance with this heightened sense of smell, Kv1.3-/- mice have glomeruli or olfactory coding units that are smaller and more numerous than those of wild-type mice. These data suggest that Kv1.3 plays a far more reaching role in signal transduction, development, and olfactory coding than that of the classically defined role of a potassium channel-to shape excitability by influencing membrane potential.

Formation of intermediate-conductance calcium-activated potassium channels by interaction of Slack and Slo subunits.

Large-conductance calcium-activated potassium channels (maxi-K channels) have an essential role in the control of excitability and secretion. Only one gene Slo is known to encode maxi-K channels, which are sensitive to both membrane potential and intracellular calcium. We have isolated a potassium channel gene called Slack that is abundantly expressed in the nervous system. Slack channels rectify outwardly with a unitary conductance of about 25-65 pS and are inhibited by intracellular calcium. However, when Slack is co-expressed with Slo, channels with pharmacological properties and single-channel conductances that do not match either Slack or Slo are formed. The Slack/Slo channels have intermediate conductances of about 60-180 pS and are activated by cytoplasmic calcium. Our findings indicate that some intermediate-conductance channels in the nervous system may result from an interaction between Slack and Slo channel subunits.

Mitochondrial factors with dual roles in death and survival.

At least in mammals, we have some understanding of how caspases facilitate mitochondria-mediated cell death, but the biochemical mechanisms by which other factors promote or inhibit programmed cell death are not understood. Moreover, most of these factors are only studied after treating cells with a death stimulus. A growing body of new evidence suggests that cell death regulators also have 'day jobs' in healthy cells. Even caspases, mitochondrial fission proteins and pro-death Bcl-2 family proteins appear to have normal cellular functions that promote cell survival. Here, we review some of the supporting evidence and stretch beyond the evidence to seek an understanding of the remaining questions.

Regulation of potassium channels by protein kinases.

Studies of the role of protein phosphorylation in the modulation of neuronal excitability are beginning to identify specific sites on ion channels that are substrates for serine/threonine kinases and that contribute to short-term and long-term regulation of current amplitude and kinetics. In addition, it is becoming apparent that phosphorylation of tyrosine residues may produce acute changes in the characteristics of ion channels. These recent findings are best illustrated by examining the Shaker superfamily of potassium channels.

Casein kinase 2 determines the voltage dependence of the Kv3.1 channel in auditory neurons and transfected cells.

The Kv3.1 potassium channel can be distinguished from most other delayed rectifier channels by its very high threshold of activation and lack of use-dependent inactivation. This allows neurons that express this channel to fire at very high frequencies. We have now found that this feature of the Kv3.1 channel is strongly influenced by its constitutive phosphorylation by the enzyme casein kinase II. Using stably transfected Chinese hamster ovary cells expressing Kv3.1, we show that Kv3.1 is highly phosphorylated under basal conditions. Whole-cell patch clamp recordings were used to characterize the electrophysiological consequence of dephosphorylation using alkaline phosphatase. This enzyme produced an increase in whole-cell conductance and shifted the voltage dependence of activation to more negative potentials by >20 mV. In addition, a similar shift in the voltage dependence of inactivation was observed. These findings were also confirmed in native Kv3.1 channels expressed in medial nucleus of the trapezoid body (MNTB) neurons. Furthermore, inhibitors of casein kinase 2 mimicked the effect of phosphatase treatment on voltage-dependent activation and inactivation, whereas inhibitors of protein kinase C failed to alter these parameters. The combination of biochemical and electrophysiological evidence suggests that the biophysical characteristics of Kv3.1 that are important to its role in MNTB neurons, allowing them to follow high-frequency stimuli with fidelity, are largely determined by phosphorylation of the channel.

Dexamethasone increases potassium channel messenger RNA and activity in clonal pituitary cells.

Glucocorticoid hormones are released as part of the stress response and regulate secretion by the pituitary. Since the activity of ion channels also influences secretion, we examined the effect of the glucocorticoid agonist dexamethasone on ion channel expression. K+ channel mRNA was detected in rat hypothalamus and anterior pituitary, with probes derived from the rat Kv1 gene, a member of the mammalian voltage-gated K+ channel superfamily. High levels were also detected in PRL-secreting clonal (GH3 and GH4C1) rat pituitary cells. Dexamethasone rapidly increased the steady state concentration of Kv1 mRNA in GH3 cells in a dose-dependent manner. This change in gene expression was accompanied by an increase in whole cell voltage-gated K+ current [lk(i)] with similar pharmacology to the Kv1 gene product. Our findings indicate that hormones may act directly on excitable cells to produce long term effects on electrical activity and secretion by regulating K+ channel expression.

The bag cell neurons of Aplysia. A model for the study of the molecular mechanisms involved in the control of prolonged animal behaviors.

Egg laying in Aplysia involves a well-characterized series of behaviors that can last for several hours. The behaviors are controlled by two bilateral clusters of peptidergic neurons in the abdominal ganglion. Following brief stimulation, these neurons, which have been termed the bag cell neurons, undergo a sequence of changes in their excitability lasting many hours. The bag cell neurons have served as a model system for studying the molecular mechanisms involved in the synthesis, processing, and release of neuroactive peptides and in the regulation of prolonged changes in neuronal excitability.

Localization of a high threshold potassium channel in the rat cochlear nucleus.

Potassium channels play a major role in determining the pattern and frequency of neuronal firing. In the cochlear nucleus (CN), various morphologically defined types of neurons have different responses to a sound. We have previously identified one type of cloned K+ channel, termed Kv3.1, which is highly expressed in many auditory neurons. Expression studies indicate that Kv3.1 channels have an unusually high threshold for activation. In this study, we used both in situ hybridization and immunohistochemistry to examine the expression patterns of the Kv3.1 channel in the CN. In the ventral CN, bushy cells hybridized strongly with Kv3.1 specific probes and a subpopulation of stellate/multipolar cells hybridized with Kv3.1 probes. In the dorsal CN, pyramidal and large multipolar/giant cells expressed Kv3.1 mRNA. Abundant Kv3.1 immunolabeling was also observed in the CN. The pattern of immunolabeling revealed that the Kv3.1 protein is distributed along the soma, proximal dendrites, unmyelinated axons, and axon terminals of stained neurons. In the case of pyramidal and octopus cells, no immunolabeling was detected at the somata, even though these cells expressed Kv3.1 mRNA. Computer simulations were used to explore the functional role of the Kv3.1 channel. The simulations indicate that Kv3.1 conductances may contribute to repolarization of large synaptic potentials. When stimulated at high frequencies, the presence of Kv3.1 enhances the ability of a model cell with some of the features of bushy cells to follow high frequency input with temporal precision.

Localization of two high-threshold potassium channel subunits in the rat central auditory system.

The firing pattern of auditory neurons is determined in part by the type of voltage-sensitive potassium channels expressed. The expression patterns for two high-threshold potassium channels, Kv3.1 and Kv3.3, that differ in inactivation properties were examined in the rat auditory system. The positive activation voltage and rapid deactivation kinetics of these channels provide rapid repolarization of action potentials with little effect on action potential threshold. In situ hybridization experiments showed that Kv3.3 mRNA was highly expressed in most auditory neurons in the rat brainstem, whereas Kv3.1 was expressed in a more limited population of auditory neurons. Notably, Kv3.1 mRNA was not expressed in neurons of the medial and lateral superior olive and a subpopulation of neurons in the ventral nucleus of the lateral lemniscus. These results suggest that Kv3.3 channels may be the dominant Kv3 subfamily member expressed in brainstem auditory neurons and that, in some auditory neurons, Kv3.1 and Kv3.3 may coassemble to form functional channels. The localization of Kv3.1 protein was examined immunohistochemically. The distribution of stained somata and neuropil varied across auditory nuclei and correlated with the distribution of Kv3.1 mRNA-expressing neurons and their terminal arborizations, respectively. The intensity of Kv3.1 immunoreactivity varied across the tonotopic map in the medial nucleus of the trapezoid body with neurons responding best to high-frequency tones most intensely labeled. Thus, auditory neurons may vary the types and amount of K(+) channel expression in response to synaptic input to subtly tune their firing properties.