Leonard K. Kaczmarek

High-frequency firing helps replenish the readily releasable pool of synaptic vesicles.

Synapses in the central nervous system undergo various short- and long-term changes in their strength, but it is often difficult to distinguish whether presynaptic or postsynaptic mechanisms are responsible for these changes. Using patch-clamp recording from giant synapses in the mouse auditory brainstem, we show here that short-term synaptic depression can be largely attributed to rapid depletion of a readily releasable pool of vesicles. Replenishment of this pool is highly dependent on the recent history of synaptic activity. High-frequency stimulation of presynaptic terminals significantly enhances the rate of replenishment. Broadening the presynaptic action potential with the potassium-channel blocker tetraethylammonium, which increases Ca2+ entry, further enhances the rate of replenishment. As this increase can be suppressed by the Ca2+-channel blocker Cd2+ or by the Ca2+ buffer EGTA, we conclude that Ca2+ influx through voltage-gated Ca2+ channels is the key signal that dynamically regulates the refilling of the releasable pool of synaptic vesicles in response to different patterns of inputs.

Modulation of mitochondrial function by endogenous Zn2+ pools

Recent evidence suggests that intracellular Zn2+ accumulation contributes to the neuronal injury that occurs in epilepsy or ischemia in certain brain regions, including hippocampus, amygdala, and cortex. Although most attention has been given to the vesicular Zn2+ that is released into the synaptic space and may gain entry to postsynaptic neurons, recent studies have highlighted pools of intracellular Zn2+ that are mobilized in response to stimulation. One such Zn2+ pool is likely bound to cytosolic proteins, like metallothioneins. Applying imaging techniques to cultured cortical neurons, this study provides novel evidence for the presence of a mitochondrial pool distinct from the cytosolic protein or ligand-bound pool. These pools can be pharmacologically mobilized largely independently of each other, with Zn2+ release from one resulting in apparent net Zn2+ transfer to the other. Further studies found evidence for complex and potent effects of Zn2+ on isolated brain mitochondria. Submicromolar levels, comparable to those that might occur on strong mobilization of intracellular compartments, induced membrane depolarization (loss of Δψm), increases in currents across the mitochondrial inner membrane as detected by direct patch clamp recording of mitoplasts, increased O2 consumption and decreased reactive oxygen species (ROS) generation, whereas higher levels decreased O2 consumption and increased ROS generation. Finally, strong mobilization of protein-bound Zn2+ appeared to induce partial loss of Δψm, suggesting that movement of Zn2+ between cytosolic and mitochondrial pools might be of functional significance in intact neurons.

The role of protein kinase C in the regulation of ion channels and neurotransmitter release

Abstract Protein kinase C is an enzyme whose activity depends on its lipid environment and which is activated by the second messenger, diacylglycerol. The high concentrations of protein kinase C in the nervous system compared to many other tissues suggest that this enzyme plays an important role in the regulation of neuronal activity. Its physiological activator, diacylglycerol, is produced transiently in many types of cells in response to synaptic or hormonal stimulation. In intact cells, the activity of protein kinase C can be stimulated by low concentrations of phorbol esters or by synthetic diacylglycerols. Both biochemical and electrophysiological investigations using activators of this enzyme have indicated that protein kinase C regulates calcium, potassium and chloride channels, and that changes in its activity control the amount of neurotransmitter released by nerve cells.

Contribution of the Kv3.1 potassium channel to high-frequency firing in mouse auditory neurones.

1 Using a combination of patch‐clamp, in situ hybridization and computer simulation techniques, we have analysed the contribution of potassium channels to the ability of a subset of mouse auditory neurones to fire at high frequencies. 2 Voltage‐clamp recordings from the principal neurones of the medial nucleus of the trapezoid body (MNTB) revealed a low‐threshold dendrotoxin (DTX)‐sensitive current (ILT) and a high‐threshold DTX‐insensitive current (IHT). 3 I HT displayed rapid activation and deactivation kinetics, and was selectively blocked by a low concentration of tetraethylammonium (TEA; 1 mm). 4 The physiological and pharmacological properties of IHT very closely matched those of the Shaw family potassium channel Kv3.1 stably expressed in a CHO cell line. 5 An mRNA probe corresponding to the C‐terminus of the Kv3.1 channel strongly labelled MNTB neurones, suggesting that this channel is expressed in these neurones. 6 TEA did not alter the ability of MNTB neurones to follow stimulation up to 200 Hz, but specifically reduced their ability to follow higher frequency impulses. 7 A computer simulation, using a model cell in which an outward current with the kinetics and voltage dependence of the Kv3.1 channel was incorporated, also confirmed that the Kv3.1‐ like current is essential for cells to respond to a sustained train of high‐frequency stimuli. 8 We conclude that in mouse MNTB neurones the Kv3.1 channel contributes to the ability of these cells to lock their firing to high‐frequency inputs.

Cloning and expression of cDNA and genomic clones encoding three delayed rectifier potassium channels in rat brain

Rat brain cDNA and genomic clones encoding three K+ channels, Kv1, Kv2, and Kv3, have been isolated by screening with Shaker probes and encode proteins of 602, 530, and 525 amino acids. Each of the deduced protein sequences contains six hydrophobic domains (including an S4-type region characteristic of many voltage-gated channels) and are 68%-72% identical to each other overall. Transcripts of approximately 3.5, approximately 6.5, and approximately 9.5 kb encode Kv1, Kv2, and Kv3, respectively. The Kv2 mRNA is expressed only in brain, whereas the Kv1 and Kv3 transcripts are found in several other tissues as well. There is a marked increase in the amount of Kv1 mRNA in cardiac tissue during development and a similar, but less pronounced, increase of both this mRNA and the Kv2 transcript in brain. RNAs synthesized in vitro from the three clones induce voltage- and time-dependent, delayed rectifier-like K+ currents when injected into Xenopus oocytes, demonstrating that they encode functional K+ channels.

De novo gain-of-function KCNT1 channel mutations cause malignant migrating partial seizures of infancy.

Malignant migrating partial seizures of infancy (MMPSI) is a rare epileptic encephalopathy of infancy that combines pharmacoresistant seizures with developmental delay. We performed exome sequencing in three probands with MMPSI and identified de novo gain-of-function mutations affecting the C-terminal domain of the KCNT1 potassium channel. We sequenced KCNT1 in 9 additional individuals with MMPSI and identified mutations in 4 of them, in total identifying mutations in 6 out of 12 unrelated affected individuals. Functional studies showed that the mutations led to constitutive activation of the channel, mimicking the effects of phosphorylation of the C-terminal domain by protein kinase C. In addition to regulating ion flux, KCNT1 has a non-conducting function, as its C terminus interacts with cytoplasmic proteins involved in developmental signaling pathways. These results provide a focus for future diagnostic approaches and research for this devastating condition.

hSK4/hIK1, a Calmodulin-binding KCa Channel in Human T Lymphocytes ROLES IN PROLIFERATION AND VOLUME REGULATION

Human T lymphocytes express a Ca2+-activated K+ current (IK), whose roles and regulation are poorly understood. We amplified hSK4 cDNA from human T lymphoblasts, and we showed that its biophysical and pharmacological properties when stably expressed in Chinese hamster ovary cells were essentially identical to the native IK current. In activated lymphoblasts, hSK4 mRNA increased 14.6-fold (Kv1.3 mRNA increased 1.3-fold), with functional consequences. Proliferation was inhibited when Kv1.3 and IK were blocked in naive T cells, but IK block alone inhibited re-stimulated lymphoblasts. IK and Kv1.3 were involved in volume regulation, but IK was more important, particularly in lymphoblasts. hSK4 lacks known Ca2+-binding sites; however, we mapped a Ca2+-dependent calmodulin (CaM)-binding site to the proximal C terminus (Ct1) of hSK4. Full-length hSK4 produced a highly negative membrane potential (V m ) in Chinese hamster ovary cells, whereas the channels did not function when either Ct1 or the distal C terminus was deleted (V m ∼0 mV). Native IK (but not expressed hSK4) current was inhibited by CaM and CaM kinase antagonists at physiological V m values, suggesting modulation by an accessory molecule in native cells. Our results provide evidence for increased roles for IK/hSK4 in activated T cell functions; thus hSK4 may be a promising therapeutic target for disorders involving the secondary immune response.

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.

Cloning and localization of the hyperpolarization-activated cyclic nucleotide-gated channel family in rat brain

Rhythmic firing in brain and heart is mediated by pacemaker channels that are activated by hyperpolarization and regulated directly by cyclic nucleotides. Recent work has identified a new gene family that encodes such channels, which are termed hyperpolarization-activated, cyclic nucleotide-gated (HCN) channels. In this study, we report the molecular cloning and localization by in situ hybridization of HCN1-4 in adult rat brain. The rat HCN1-4 clones show high homology to the deduced amino acid sequence of the mouse channels (>97% identity). The mRNA expression of the four channels in adult brain was evaluated in a systematic manner from the olfactory bulb to lower brain stem nuclei. Each mRNA demonstrated a unique pattern of distribution. HCN1 expression is highly enriched in cerebral cortex, hippocampus, cerebellum, and facial motor nucleus; HCN2 is highly abundant in mamillary bodies, pontine nucleus, ventral cochlear nucleus, and nucleus of the trapezoid body; HCN3 expression is most pronounced in supraoptic nucleus of hypothalamus; and HCN4 expression is most abundant in medial habenula and anterior and principal relay nuclei of the thalamus. These variations in regional specificity of HCN channels could generate important differences in neuronal pacemaker activity across brain systems.

The Sodium-Activated Potassium Channel Is Encoded by a Member of the Slo Gene Family

Na(+)-activated potassium channels (K(Na)) have been identified in cardiomyocytes and neurons where they may provide protection against ischemia. We now report that K(Na) is encoded by the rSlo2 gene (also called Slack), the mammalian ortholog of slo-2 in C. elegans. rSlo2, heterologously expressed, shares many properties of native K(Na) including activation by intracellular Na(+), high conductance, and prominent subconductance states. In addition to activation by Na(+), we report that rSLO-2 channels are cooperatively activated by intracellular Cl(-), similar to C. elegans SLO-2 channels. Since intracellular Na(+) and Cl(-) both rise in oxygen-deprived cells, coactivation may more effectively trigger the activity of rSLO-2 channels in ischemia. In C. elegans, mutational and physiological analysis revealed that the SLO-2 current is a major component of the delayed rectifier. We demonstrate in C. elegans that slo-2 mutants are hypersensitive to hypoxia, suggesting a conserved role for the slo-2 gene subfamily.