Mutsuyuki Sugimori

ELECTROPHYSIOLOGICAL PROPERTIES OF IN VITRO PURKINJE CELL DENDRITES IN MAMMALIAN CEREBELLAR SLICES

1. Intradendritic recordings from Purkinje cells in vitro indicate that white matter stimulation produces large synaptic responses by the activation of the climbing fibre afferent, but antidromic potentials do not actively invade the dendritic tree. 2. Climbing fibre responses may be reversed in a manner similar to that observed at the somatic level. However, the reversal does not show the biphasicity often seen at somatic level. 3. Input resistance of these dendrites was found to range from 15 to 30 M omega. The non‐linear properties seen at the somatic level for depolarizing currents are also encountered here. However, there seems to be less anomalous rectification. 4. Detailed analysis of repetitive firing of Purkinje cells elicited by outward DC current shows that, as in the case of the antidromic invasion, the fast somatic potentials (s.s.) do not invade the dendrite actively. However, the dendritic spike bursts (d.s.b.s) interposed between the s.s. potentials are most prominent at dendritic level. 5. Two types of voltage‐dependent Ca responses were observed. At low stimulus level a plateau‐like depolarization is accompanied by a prominent conductance change; further depolarization produces large dendritic action potentials. These two classes of response are TTX‐resistant but are blocked by Cd, Co, Mn or D600, or by the removal of extracellular Ca. 6. Following blockage of the Ca conductance, plateau potentials produced by a non‐inactivating Na conductance are observed mainly near the soma indicating that this voltage‐dependent conductance is probably associated with the somatic membrane. 7. Spontaneous firing in Purkinje cell dendrites is very similar to that observed at the soma. However, the amplitude of these bursts is larger at dendritic level. It is further concluded that these TTX‐insensitive spikes are generated at multiple sites along the dendritic tree. 8. Six ionic conductances seem to be involved in Purkinje cell electroresponsiveness: (a) an inactivating and (b) a non‐inactivating Na conductance at or near the soma, (c) a spike‐ and (d) a plateau‐generating Ca conductance, and (e) voltage‐dependent and (f) Ca‐dependent K currents. 9. The possible role of these conductances in Purkinje cell integration is discussed.

Distribution and functional significance of the P-type, voltage-dependent Ca2+ channels in the mammalian central nervous system

In addition to the three types of voltage-dependent calcium channels presently recognized in the CNS, the L-, the T- and the N-types, a fourth distinct type known as the P-type channel has recently been described. This channel, initially recognized in Purkinje cells (and thus the name), is not blocked by dihydropyridines or by omega-conotoxin (GVIA), but is blocked by native funnel-web spider venom and by a polyamine (FTX) extracted from such venom. In addition, a synthetic polyamine (sFTX) has been produced that also specifically blocks P-channels in brain slices and at the neuromuscular junction, and blocks presynaptic Ca2+ currents in other vertebrate and invertebrate forms, as well as channels expressed in Xenopus oocytes following CNS mRNA injections. Using sFTX to form an affinity gel, a protein was isolated and reconstituted into lipid bilayers where it manifests single-channel properties that are electrophysiologically and pharmacologically similar to those of the native P-channels. Rabbits immunized with the isolated protein produced a polyclonal antibody that gave a positive western blot with the purified P-channel protein and generated a reaction product at specific sites in the CNS that agree with the physiological distribution of P-channel activity.

P-type calcium channels in the somata and dendrites of adult cerebellar purkinje cells

The pharmacological and single-channel properties of Ca2+ channels were studied in the somata and dendrites of adult cerebellar Purkinje cells. The Ca2+ channels were exclusively of the high threshold type: low threshold Ca2+ channels were not found. These high threshold channels were not blocked by omega-conotoxin GVIA and were inhibited rather than activated by BAY K 8644. They were therefore pharmacologically distinct from high threshold N- and L-type channels. Funnel web spider toxin was an effective blocker. The channels opened to conductance levels of 9, 14, and 19 pS (in 110 mM Ba2+). These slope conductances were in the range of those reported for N- and L-type channels. Our results are in agreement with previous reports suggesting that Ca2+ channels in Purkinje cells can be classified as P-type channels according to their pharmacology. The results also suggest that distinctions among Ca2+ channel types based on the single-channel conductance are not definitive.

Ionic currents and firing patterns of mammalian vagal motoneurons in vitro.

The electrophysiological properties of guinea-pig dorsal vagal motoneurons were studied in an in vitro slice preparation. Antidromic, orthodromic and direct stimulation of the neurons demonstrated that the action potential is comprised of several distinct components: a fast initial spike followed by afterdepolarization and an early and a late afterhyperpolarizations. The fast initial spike and the early afterhyperpolarization were blocked by tetrodotoxin and tetraethylammonium ions, respectively. The afterdepolarization (present on the falling phase of the spike) and the late afterhyperpolarization were blocked by the addition of ions known to block calcium conductance (CdCl2, CoCl2 or MnCl2), indicating close association between these two potentials. Prolonged outward current injection through the recording electrode produced two different firing patterns, depending on the initial level of the membrane potential. From resting potential (usually -60 mV) the firing pattern was characterized by a short train of action potentials appearing shortly after the onset of the depolarization step. By contrast, when the depolarization was delivered from a hyperpolarized membrane potential level, a short train of repetitive firing appeared after an initial delay of 300-400 ms. The membrane current responsible for this initial reduction in excitability was studied by means of a single-electrode voltage-clamp technique. The magnitude, direction and kinetics of such current flow are consistent with the presence of early potassium current (IA), partly inactive at the resting potential. Synaptic activation of vagal motoneurons could be obtained by electrical stimulation of the tissue surrounding the vagal nucleus or by direct activation of the vagal nerve. Perivagal stimulation generated excitatory and inhibitory synaptic potentials which could be reversed by shifting the membrane potential. Vagal nerve stimulation, in addition to the antidromic activation of the cells, generated depolarizing responses which were unitary in nature and did not show much sensitivity to shifts in membrane potential. Perivagal and vagal nerve-evoked depolarizations could generate action potentials as well as partial dendritic spikes. We conclude that spike electroresponsiveness in vagal motoneurons is generated by voltage-dependent Na+ and Ca2+ conductances. In addition, the Ca2+-dependent current triggers a K+ conductance which is responsible for modulating the firing frequency obtained from the normal resting level.(ABSTRACT TRUNCATED AT 400 WORDS)

The concept of calcium concentration microdomains in synaptic transmission

Ever since the initial measurements of presynaptic calcium currents it has been evident that calcium triggers transmitter release quite rapidly. Several models indicate, as did the initial voltage clamp measurements, that the calcium concentration triggering such release could be very high at the entry site and that this concentration should be very short lasting. In order to determine this time course, calcium entry was studied at the squid giant synapse by imaging light emission from n-aequorin-J, intracellularly injected into the presynaptic terminal. The imaging utilized a video system capable of acquiring 4000 frames per sec. The results indicate that the calcium entry, triggered by action potentials, reaches a peak within 200 musec and has an overall duration of close to 800 musec, closely matching the duration of the presynaptic calcium current determined by voltage clamp results under similar conditions.

1-Methyl-4-phenylpyridinium affects fast axonal transport by activation of caspase and protein kinase C

Parkinsons disease (PD), a late-onset condition characterized by dysfunction and loss of dopaminergic neurons in the substantia nigra, has both sporadic and neurotoxic forms. Neurotoxins such as 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine and its metabolite 1-methyl-4-phenylpyridinium (MPP+) induce PD symptoms and recapitulate major pathological hallmarks of PD in human and animal models. Both sporadic and MPP+-induced forms of PD proceed through a “dying-back” pattern of neuronal degeneration in affected neurons, characterized by early loss of synaptic terminals and axonopathy. However, axonal and synaptic-specific effects of MPP+ are poorly understood. Using isolated squid axoplasm, we show that MPP+ produces significant alterations in fast axonal transport (FAT) through activation of a caspase and a previously undescribed protein kinase C (PKCδ) isoform. Specifically, MPP+ increased cytoplasmic dynein-dependent retrograde FAT and reduced kinesin-1-mediated anterograde FAT. Significantly, MPP+ effects were independent of both nuclear activities and ATP production. Consistent with its effects on FAT, MPP+ injection in presynaptic domains led to a dramatic reduction in the number of membranous profiles. Changes in availability of synaptic and neurotrophin-signaling components represent axonal and synaptic-specific effects of MPP+ that would produce a dying-back pathology. Our results identify a critical neuronal process affected by MPP+ and suggest that alterations in vesicle trafficking represent a primary event in PD pathogenesis. We propose that PD and other neurodegenerative diseases exhibiting dying-back neuropathology represent a previously undescribed category of neurological diseases characterized by dysfunction of vesicle transport and associated with the loss of synaptic function.

Synaptic transmission block by presynaptic injection of oligomeric amyloid beta

Early Alzheimers disease (AD) pathophysiology is characterized by synaptic changes induced by degradation products of amyloid precursor protein (APP). The exact mechanisms of such modulation are unknown. Here, we report that nanomolar concentrations of intraaxonal oligomeric (o)Aβ42, but not oAβ40 or extracellular oAβ42, acutely inhibited synaptic transmission at the squid giant synapse. Further characterization of this phenotype demonstrated that presynaptic calcium currents were unaffected. However, electron microscopy experiments revealed diminished docked synaptic vesicles in oAβ42-microinjected terminals, without affecting clathrin-coated vesicles. The molecular events of this modulation involved casein kinase 2 and the synaptic vesicle rapid endocytosis pathway. These findings open the possibility of a new therapeutic target aimed at ameliorating synaptic dysfunction in AD.

High-Resolution Measurement of the Time Course of Calcium-Concentration Microdomains at Squid Presynaptic Terminals

Transmitter release is considered to be a secretory event triggered by localized calcium influx which, by binding to a low-affinity Ca2+ site at the presynaptic active zone, initiates vesicular exocytosis (1-7). In previous experiments with aequorin-loaded presynaptic terminals we visualized, upon tetanic presynaptic stimulation, small points of light produced by calcium concentration microdomains of about 300 microM (5). These microdomains had a diameter of about 0.5 microns (5) and covered 5-10% of the total presynaptic membrane with an average density of 8.4 microns2 per 100 microns2, corresponding closely to the size and distribution of the active zones in that junction (6, 7). To understand in more detail the nature of these concentration microdomains, we obtained rapid video images (400/s) after injecting the photoprotein n-aequorin-J into the presynaptic terminals of squid giant synapses. Using that experimental approach, we determined that microdomains evoked by presynaptic spike activation had a duration of about 800 microseconds. Spontaneous quantum emission domains (QEDs) observed at about the same locations as the microdomains were smaller in amplitude, shorter in duration, and less frequent. These results illustrate the time course of the calcium concentration profiles responsible for transmitter release. Their extremely short duration compares closely with that of calcium current flow during a presynaptic action potential and indicates that, as theorized in the past (6-8), intracellular calcium concentration at the active zone remains high only for the duration of transmembrane calcium flow.

Synaptic vesicle exocytosis in hippocampal synaptosomes correlates directly with total mitochondrial volume.

Synaptic plasticity in many regions of the central nervous system leads to the continuous adjustment of synaptic strength, which is essential for learning and memory. In this study, we show by visualizing synaptic vesicle release in mouse hippocampal synaptosomes that presynaptic mitochondria and, specifically, their capacities for ATP production are essential determinants of synaptic vesicle exocytosis and its magnitude. Total internal reflection microscopy of FM1-43 loaded hippocampal synaptosomes showed that inhibition of mitochondrial oxidative phosphorylation reduces evoked synaptic release. This reduction was accompanied by a substantial drop in synaptosomal ATP levels. However, cytosolic calcium influx was not affected. Structural characterization of stimulated hippocampal synaptosomes revealed that higher total presynaptic mitochondrial volumes were consistently associated with higher levels of exocytosis. Thus, synaptic vesicle release is linked to the presynaptic ability to regenerate ATP, which itself is a utility of mitochondrial density and activity.

Is low molecular weight heparin a neuroprotectant

This communication reports the results of investigations on the effect of low molecular weight heparin (LMWH) on intraneuronal calcium release, and considers its possible relevance to the treatment of ischemic stroke. It previously was shown that intraneuronal injection of conventional heparin (MW 12,000) in vitro prevents glutamate-induced calcium release from intracellular stores through its blocking action on IP3 (inositol-1,4,5-triphosphate) receptors, and thus interferes with events occurring in the ischemic cascade. In the experiments reported herein, a LMWH of MW 4500 was shown to have these same effects when injected into a Purkinje cell in an in vitro cerebellar slice preparation, and also when administered externally (bath application). By contrast, conventional heparin works only when injected into the cell; bath application has no effect. The results are interpreted to mean that the larger conventional heparin molecule cannot pass through the cell membrane, while the smaller LMWH molecule does indeed enter the cell. In a clinical trial, LMWH begun within 48 hours of ischemic stroke onset in humans improved outcome at 6 months; conventional heparin given in a similar trial was without benefit. That one anticoagulant was beneficial while another failed suggests the possibility that the difference was independent of effect on the clotting system. The experimental data herein reported support the view that LMWH may benefit stroke victims by an action directly cytoprotective against the consequences of neuronal ischemia.