Immunohistochemical study on the distribution of neuronal voltage-gated calcium channels in the rat cerebellum

Aging of cerebellar Purkinje cells

Cerebellar Purkinje cells (PCs), the sole output neurons in the cerebellar cortex, play an important role in the cerebellar circuit. PCs appear to be rather sensitive to aging, exhibiting significant changes in both morphology and function during senescence. This article reviews such changes during the normal aging process, including a decrease in the quantity of cells, atrophy in the soma, retraction in the dendritic arborizations, degeneration in the subcellular organelles, a decline in synapse density, disorder in the neurotransmitter system, and alterations in electrophysiological properties. Although these deteriorative changes occur during aging, compensatory mechanisms exist to counteract the impairments in the aging PCs. The possible neural mechanisms underlying these changes and potential preventive treatments are discussed.

Immunohistochemical study on the expression of calcium binding proteins (calbindin-D28k, calretinin, and parvalbumin) in the cerebellum of the nNOS knock-out(-/-) mice

Nitric Oxide (NO) actively participates in the regulation of neuronal intracellular Ca²⁺ levels by modulating the activity of various channels and receptors. To test the possibility that modulation of Ca²⁺ buffer protein expression level by NO participates in this regulatory effect, we examined expression of calbindin-D28k, calretinin, and parvalbumin in the cerebellum of neuronal NO synthase knock-out (nNOS^(-/-)) mice using immunohistochemistry. We observed that in the cerebellar cortex of the nNOS^(-/-) mice, expression of calbindin-D28k and parvalbumin were significantly increased while expression of calretinin was significantly decreased. These results suggest another mechanism by which NO can participate in the regulation of Ca²⁺ homeostasis.

Deletion of Cav2.1(alpha1(A)) subunit of Ca2+-channels impairs synaptic GABA and glutamate release in the mouse cerebellar cortex in cultured slices

Deletion of both alleles of the P/Q-type Ca(2+)-channel Ca(v)2.1(alpha(1A)) subunit gene in mouse leads to severe ataxia and early death. Using cerebellar slices obtained from 10 to 15 postnatal days mice and cultured for at least 3 weeks in vitro, we have analysed the synaptic alterations produced by genetically ablating the P/Q-type Ca(2+)-channels, and compared them with the effect of pharmacological inhibition of the P/Q- or N-type channels on wild-type littermate mice. Analysis of spontaneous synaptic currents recorded in Purkinje cells (PCs) indicated that the P/Q-type channels play a prominent role at the inhibitory synapses afferent onto the PCs, with the effect of deleting Ca(v)2.1(alpha(1A)) partially compensated. At the granule cell (GC) to PC synapses, both N- and P/Q-type Ca(2+)-channels were found playing a role in glutamate exocytosis, but with no significant phenotypic compensation of the Ca(v)2.1(alpha(1A)) deletion. We also found that the P/Q- but not N-type Ca(2+)-channel is indispensable at the autaptic contacts between PCs. Tuning of the GC activity implicates both synaptic and sustained extrasynaptic gamma-aminobutyric acid (GABA) release, only the former was greatly impaired in the absence of P/Q-type Ca(2+)-channels. Overall, our data demonstrate that both P/Q- and N-type Ca(2+)-channels play a role in glutamate release, while the P/Q-type is essential in GABA exocytosis in the cerebellum. Contrary to the other regions of the CNS, the effect of deleting the Ca(v)2.1(alpha(1A)) subunit is partially or not compensated at the inhibitory synapses. This may explain why cerebellar ataxia is observed at the mice lacking functional P/Q-type channels.

Large-conductance calcium-activated potassium channels in purkinje cell plasma membranes are clustered at sites of hypolemmal microdomains

Calcium-activated potassium channels have been shown to be critically involved in neuronal function, but an elucidation of their detailed roles awaits identification of the microdomains where they are located. This study was undertaken to unravel the precise subcellular distribution of the large-conductance calcium-activated potassium channels (called BK, KCa1.1, or Slo1) in the somatodendritic compartment of cerebellar Purkinje cells by means of postembedding immunogold cytochemistry and SDS-digested freeze-fracture replica labeling (SDS-FRL). We found BK channels to be unevenly distributed over the Purkinje cell plasma membrane. At distal dendritic compartments, BK channels were scattered over the plasma membrane of dendritic shafts and spines but absent from postsynaptic densities. At the soma and proximal dendrites, BK channels formed two distinct pools. One pool was scattered over the plasma membrane, whereas the other pool was clustered in plasma membrane domains overlying subsurface cisterns. The labeling density ratio of clustered to scattered channels was about 60:1, established in SDS-FRL. Subsurface cisterns, also called hypolemmal cisterns, are subcompartments of the endoplasmic reticulum likely representing calciosomes that unload and refill Ca2+ independently. Purkinje cell subsurface cisterns are enriched in inositol 1,4,5-triphosphate receptors that mediate the effects of several neurotransmitters, hormones, and growth factors by releasing Ca2+ into the cytosol, generating local Ca2+ sparks. Such increases in cytosolic [Ca2+] may be sufficient for BK channel activation. Clustered BK channels in the plasma membrane may thus participate in building a functional unit (plasmerosome) with the underlying calciosome that contributes significantly to local signaling in Purkinje cells.

Purkinje cell input to cerebellar nuclei in tottering: ultrastructure and physiology

Homozygous tottering mice are spontaneous ataxic mutants, which carry a mutation in the gene encoding the ion pore of the P/Q-type voltage-gated calcium channels. P/Q-type calcium channels are prominently expressed in Purkinje cell terminals, but it is unknown to what extent these inhibitory terminals in tottering mice are affected at the morphological and electrophysiological level. Here, we investigated the distribution and ultrastructure of their Purkinje cell terminals in the cerebellar nuclei as well as the activities of their target neurons. The densities of Purkinje cell terminals and their synapses were not significantly affected in the mutants. However, the Purkinje cell terminals were enlarged and had an increased number of vacuoles, whorled bodies, and mitochondria. These differences started to occur between 3 and 5 weeks of age and persisted throughout adulthood. Stimulation of Purkinje cells in adult tottering mice resulted in inhibition at normal latencies, but the activities of their postsynaptic neurons in the cerebellar nuclei were abnormal in that the frequency and irregularity of their spiking patterns were enhanced. Thus, although the number of their terminals and their synaptic contacts appear quantitatively intact, Purkinje cells in tottering mice show several signs of axonal damage that may contribute to altered postsynaptic activities in the cerebellar nuclei.

Selective regulation of spontaneous activity of neurons of the deep cerebellar nuclei by N-type calcium channels in juvenile rats

The cerebellum coordinates movement and maintains body posture. The main output of the cerebellum is formed by three deep nuclei, which receive direct inhibitory inputs from cerebellar Purkinje cells, and excitatory collaterals from mossy and climbing fibres. Neurons of deep cerebellar nuclei (DCN) are spontaneously active, and disrupting their activity results in severe cerebellar ataxia. It is suggested that voltage-gated calcium channels make a significant contribution to the spontaneous activity of DCN neurons, although the exact identity of these channels is not known. We sought to delineate the functional role and identity of calcium channels that contribute to pacemaking in DCN neurons of juvenile rats. We found that in the majority of cells blockade of calcium currents results in avid high-frequency bursting, consistent with the notion that the net calcium-dependent current in DCN neurons is outward. We showed that the bursting seen in these neurons after block of calcium channels is the consequence of reduced activation of small-conductance calcium-activated (SK) potassium channels. With the use of selective pharmacological blockers we showed that L-, P/Q-, R- and T-type calcium channels do not contribute to the spontaneous activity of DCN neurons. In contrast, blockade of high-threshold N-type calcium channels increased the firing rate and caused the cells to burst. Our results thus suggest a selective coupling of N-type voltage-gated calcium channels with calcium-activated potassium channels in DCN neurons. In addition, we demonstrate the presence of a cadmium-sensitive calcium conductance coupled with SK channels, that is pharmacologically distinct from L-, N-, P/Q-, R- and T-type calcium channels.

Protease treatment of cerebellar purkinje cells renders omega-agatoxin IVA-sensitive Ca2+ channels insensitive to inhibition by omega-conotoxin GVIA

The identification of currents carried by N- and P-type Ca(2+) channels in the nervous system relies on the use of omega-conotoxin (CTx) GVIA and omega-agatoxin (Aga) IVA. The peptide omega-Aga-IVA inhibits P-type currents at nanomolar concentrations and N-type currents at micromolar concentrations. omega-CTx-GVIA blocks N-type currents, but there have been no reports that it can also inhibit P-type currents. To assess the effects of omega-CTx-GVIA on P-type channels, we made patch-clamp recordings from the soma of Purkinje cells in cerebellar slices of mature [postnatal days (P) 40-50, P40-50] and immature (P13-20) rats, in which P-type channels carry most of the Ca(2+) channel current (>/=85%). These showed that micromolar concentrations of omega-CTx-GVIA inhibited the current in P40-50 cells (66%, 3 microM; 78%, 10 microM) and in P13-20 Purkinje cells (86%, 3 muM; 89%, 10 microM). The inhibition appeared to be reversible, in contrast to the known irreversible inhibition of N-type current. Exposure of slices from young animals to the enzyme commonly used to dissociate Purkinje cells, protease XXIII, abolished the inhibition by omega-CTx-GVIA but not by omega-Aga-IVA (84%, 30 nM). Our finding that micromolar concentrations of omega-CTx-GVIA inhibit P-type currents suggests that specific block of N-type current requires the use of submicromolar concentrations. The protease-induced removal of block by omega-CTx-GVIA but not by omega-Aga-IVA indicates a selective proteolytic action at site(s) on P-type channels with which omega-CTx-GVIA interacts. It also suggests that Ca(2+) channel pharmacology in neurons dissociated using protease may not predict that in neurons not exposed to the enzyme.

Maturation of rat cerebellar Purkinje cells reveals an atypical Ca2+ channel current that is inhibited by omega-agatoxin IVA and the dihydropyridine (-)-(S)-Bay K8644

To determine if the properties of Ca2+ channels in cerebellar Purkinje cells change during postnatal development, we recorded Ca2+ channel currents from Purkinje cells in cerebellar slices of mature (postnatal days (P) 40-50) and immature (P13-20) rats. We found that at P40-50, the somatic Ca2+ channel current was inhibited by omega-agatoxin IVA at concentrations selective for P-type Ca2+ channels (approximately 85%; IC50, <1 nM) and by the dihydropyridine (-)-(S)-Bay K8644 (approximately 70%; IC50, approximately 40 nM). (-)-(S)-Bay K8644 is known to activate L-type Ca2+ channels, but the decrease in current was not secondary to the activation of L-type channels because inhibition by (-)-(S)-Bay K8644 persisted in the presence of the L-type channel blocker (R,S)-nimodipine. By contrast, at P13-20, the current was inhibited by omega-agatoxin IVA (approximately 86%; IC50, approximately 1 nM) and a minor component was inhibited by (R,S)-nimodipine (approximately 8%). The dihydropyridine (-)-(S)-Bay K8644 had no clear effect when applied alone, but in the presence of (R,S)-nimodipine it reduced the current (approximately 40%), suggesting that activation of L-type channels by (-)-(S)-Bay K8644 masks its inhibition of non-L-type channels. Our findings indicate that Purkinje neurons express a previously unrecognized type of Ca2+ channel that is inhibited by omega-agatoxin IVA, like prototypical P-type channels, and by (-)-(S)-Bay K8644, unlike classical P-type or L-type channels. During maturation, there is a decrease in the size of the L-type current and an increase in the size of the atypical Ca2+ channel current. These changes may contribute to the maturation of the electrical properties of Purkinje cells.

Endogenous release and multiple actions of secretin in the rat cerebellum

Previous studies demonstrated that secretin could modulate synaptic transmission in the rat cerebellum. In the present report, we provide evidence for the endogenous release of secretin in the cerebellum and further characterize the actions of secretin in this brain area. First, to show that secretin is released endogenously, blocks of freshly dissected cerebella were challenged with a high concentration of KCl. Incubation with KCl almost doubled the rate of secretin release. This KCl-induced release was sensitive to tetrodotoxin and cadmium suggesting the involvement of voltage-gated sodium and calcium channels. The use of specific channel blockers further revealed that L-type and P/Q-type calcium channels underlie both basal and KCl-evoked secretin release. In support of this, depolarization of Purkinje neurons in the presence of NMDA, group II mGluR and cannabinoid CB1 receptor blockers resulted in increased inhibitory postsynaptic current frequency. Second, we found that the previously reported facilitatory action of secretin on GABAergic inputs to Purkinje neurons is partly dependent on the release of endogenous glutamate. In the presence of CNQX, an AMPA/kainate receptor antagonist, the facilitatory effect of secretin on GABA release was significantly reduced. In support of this idea, application of AMPA, but not kainate receptor agonist, facilitated GABA release from inhibitory terminals, an action that was sensitive to AMPA receptor antagonists. These data indicate that a direct and an indirect pathway mediate the action of secretin in the basket cell-Purkinje neuron synapse. The results provide further and more solid evidence for the role of secretin as a neuropeptide in the mammalian CNS.

Immunohistochemical study of p47Phox and gp91Phox distributions in rat brain

NADPH oxidase is multi-component enzyme, which comprises the cytosolic proteins p40Phox, p47Phox, and p67Phox and the two membrane proteins, gp91Phox and p22Phox, and which is well characterized in phagocytic cells. NADPH oxidase is a primary source of reactive oxygen species (ROS), and recent studies indicate that free radicals and ROS might be causative factors of several brain degenerative diseases and dysfunctions. However, though previous studies have shown the presence of NADPH oxidase subunits in cell culture and mouse brain, they have not provided detailed high power resolution data. Therefore, we investigated the distributions of the p47Phox and gp91Phox subunits in rat brain using immunohistochemical approach. Cortex, hippocampus, and Purkinje cells of cerebellum were prominently stained by p47Phox and gp91Phox antibodies. As compared with the distributions of p47Phox, gp91Phox in mouse, some differences in the rat brain were observed in the hippocampus, thalamus, amygdala, reticular nucleus, and basal ganglia. Additionally, at the cellular level, most p47Phox immunoreactivity was largely confined to cell bodies and proximal portions of the dendritic tree. Taken together, the widespread observed distributions of p47Phox and gp91Phox subunits indicate that they are probably needed to maintain normal brain function.

Low threshold calcium currents in rat cerebellar Purkinje cell dendritic spines are mediated by T-type calcium channels

The functional role of low voltage activated (LVA) calcium channels in the cerebellar Purkinje cell dendritic tree is not completely understood. Since the localization of these channels will influence their possible roles in dendritic integration and induction of plasticity, we set out to characterize the LVA calcium current in Purkinje cell dendrites in acute cerebellar slices of young rats. Using a combination of electrophysiological recordings and two-photon laser scanning microscopy, we show that LVA calcium current recorded at the soma can be correlated with voltage-dependent calcium transients in Purkinje cell dendritic spines. Blocking sodium and potassium conductances allowed us to isolate and characterize a fast inactivating inward current activated positive to -55 mV. Activation and steady-state inactivation kinetics, voltage-dependent deactivation kinetics, and pharmacological experiments (using omega-agatoxin-IVA, mibefradil and nickel) show that this current is carried by T-type calcium channels. Furthermore, the LVA calcium transient observed in the dendritic spines of the Purkinje cell is well correlated with the current recorded at the soma, suggesting that T-type calcium channels are the main component of the LVA calcium input in spines. The fast rising phase of the calcium transient in spines and the absence of delay between the onset in the spine and the parent dendrite show that T-type calcium channels are present both in spines and dendrites of the Purkinje cell.

Immunohistochemical study of the distribution of neuronal voltage-gated calcium channels in the nNOS knock-out mouse cerebellum

Nitric oxide (NO) participates in synaptic plasticity, neuronal development, and apoptosis. The involvement of NO and ionic calcium in synaptic plasticity imply that NO may exert an effect on Ca2+ channels. Therefore, we investigated changes in the expressions of calcium channel subunits (Cav1.2/alpha1C, Cav1.3/alpha(1D), Cav2.1/alpha1A, and Cav2.2/alpha1B) in nNOS knock-out (-/-) (nNOS((-/-))) mouse cerebellum using an immunohistochemical approach. We found that the immunoreactivities of the Cav1.2 and Cav1.3 subunits were reduced in the cell bodies of Purkinje cells in these mice and that the signal of the Cav1.2 subunit in neurons and of the Cav1.3 subunit in the neuropils of nNOS((-/-)) mice cerebellar nuclei were significantly down-regulated. We show, for the first time, that prolonged NO deficiency in the cerebellum may affect calcium channel protein expressions, especially, of the Cav1.2 and Cav1.3 subunits.

Distinct contributions of small and large conductance Ca2+-activated K+ channels to rat Purkinje neuron function

The cerebellum is important for many aspects of behaviour, from posture maintenance and goal-oriented reaching movements to timing tasks and certain forms of learning. In every case, information flowing through the cerebellum passes through Purkinje neurons, which receive input from the two primary cerebellar afferents and generate continuous streams of action potentials that constitute the sole output from the cerebellar cortex to the deep nuclei. The tonic firing behaviour observed in Purkinje neurons in vivo is maintained in brain slices even when synaptic inputs are blocked, suggesting that Purkinje neuron activity relies to a significant extent on intrinsic conductances. Previous research has suggested that the interplay between Ca2+ currents and Ca2+-activated K+ channels (KCa channels) is important for Purkinje cell activity, but how many different KCa channel types are present and what each channel type contributes to cell behaviour remains unclear. In order to better understand the ionic mechanisms that control the behaviour of these neurons, we investigated the effects of different Ca2+ channel and KCa channel antagonists on Purkinje neurons in acute slices of rat cerebellum. Our data show that Ca2+ entering through P-type voltage-gated Ca2+ channels activates both small-conductance (SK) and large-conductance (BK) KCa channels. SK channels play a role in setting the intrinsic firing frequency, while BK channels regulate action potential shape and may contribute to the unique climbing fibre response.

Differential alterations in the distribution of voltage-gated calcium channels in aged rat cerebellum

In the present study, we used immunohistochemistry and Western blot analysis to determine region-specific changes in the distribution of voltage-gated calcium channels (VGCCs) in aged rat cerebellum. Age-dependent changes in the staining intensity of the alpha(1C) and alpha(1D) subunits were prominent in the Purkinje cells, whereas there was no change in the expression of the alpha(1A) and alpha(1B) subunits. In the aged rat, in particular, immunoreactivity for the alpha(1C) subunits were increased in the dendrites as well as in the cell bodies of Purkinje cells. On the other hand, decreases in immunoreactivity for alpha(1A) and alpha(1D) subunits were found in the molecular or granular layers. However, only alpha(1D) subunit immunoreactivity was decreased in the aged cerebellum membrane by Western blot analysis that, while not addressing regional specificity, further confirmed an age-related decrease in alpha(1D) subunit. These age-related changes in alpha(1D) subunit expression might reflect a gradual loss of regulation for L-type Ca(2+) channels in the senescent period. The first demonstration of age-related alterations in VGCC expression may provide useful data for future investigations on aging and neurodegenerative diseases.

Spatial and temporal distribution of N-type Ca(2+) channels in gerbil global cerebral ischemia

In the present study, we have investigated the spatial and temporal distribution of voltage-gated calcium channels in the gerbil model of global cerebral ischemia using immunohistochemistry. Distinct localizations of P-type (alpha(1A)), N-type (alpha(1B)), and L-type (alpha(1C) and alpha(1D)) Ca(2+) channels were observed in the hippocampus at days 1-5 after ischemic injury. However, increased expression of N-type Ca(2+) channels was detectable in brain regions vulnerable to ischemia only at days 2 and 3 after ischemic injury. The pyramidal cell bodies of CA1-3 areas and the granule cell bodies of the dentate gyrus were intensely stained at days 2 and 3 following ischemic injury. Transient changes in N-type Ca(2+) channel expression were also observed in the affected cerebral cortex and striatum at days 2 and 3 after ischemic injury. Although the present study has not addressed the multiple mechanisms contributing to the intracellular free Ca(2+) concentration ([Ca(2+)](i)) increase in the ischemic brain, the first demonstration of the transient increase in N-type Ca(2+) channels may prove useful for future investigations.

Enhanced expression of L-type Ca2+ channels in reactive astrocytes after ischemic injury in rats

In the present study, we have examined the expression of voltage-gated calcium channels in a rat model of transient focal ischemia using immunohistochemistry. Increased expression of class C L-type Ca2+ channels was clearly detected in reactive astrocytes in each region of the hippocampus 7 days after ischemic injury. On the contrary, class D L-type Ca2+ channels were not expressed in reactive astrocytes under these conditions. These patterns were also observed in reactive astrocytes in the affected cerebral cortex and fiber tracts. Our study showed the spatial and temporal localization of class C L-type Ca2+ channels in reactive astrocytes in ischemic rat brain, for the first time. The present studies may provide useful data for future investigations to understand the role of Ca2+ channels in reactive astrocytes following ischemia or glutamate toxicity.

Immunohistochemical study on the distribution of the type I and type II voltage-gated sodium channels in the gerbil cerebellum

In this study, we investigated the distribution of the type I and type II Na+ channels in the gerbil cerebellum by immunohistochemistry. Strong uniform staining for type I was observed in the granular layer, whereas there was little evidence of concentrated labeling in the cell bodies and processes of Purkinje cells. The most intense staining for type II was observed in the cell bodies and dendrites of Purkinje cells, with a strong signal in the molecular layer. This localization study has shown clearly that the type I and type II Na+ channel subunits have differential distribution in the gerbil cerebellum, for the first time. The present study may provide useful data for the future investigations to understand the roles of voltage-gated sodium channels in neurological pathways.