Gen Ohtsuki

Intrinsic Plasticity Complements Long-Term Potentiation in Parallel Fiber Input Gain Control in Cerebellar Purkinje Cells

Synaptic gain control and information storage in neural networks are mediated by alterations in synaptic transmission, such as in long-term potentiation (LTP). Here, we show using both in vitro and in vivo recordings from the rat cerebellum that tetanization protocols for the induction of LTP at parallel fiber (PF)-to-Purkinje cell synapses can also evoke increases in intrinsic excitability. This form of intrinsic plasticity shares with LTP a requirement for the activation of protein phosphatases 1, 2A, and 2B for induction. Purkinje cell intrinsic plasticity resembles CA1 hippocampal pyramidal cell intrinsic plasticity in that it requires activity of protein kinase A (PKA) and casein kinase 2 (CK2) and is mediated by a downregulation of SK-type calcium-sensitive K conductances. In addition, Purkinje cell intrinsic plasticity similarly results in enhanced spine calcium signaling. However, there are fundamental differences: first, while in the hippocampus increases in excitability result in a higher probability for LTP induction, intrinsic plasticity in Purkinje cells lowers the probability for subsequent LTP induction. Second, intrinsic plasticity raises the spontaneous spike frequency of Purkinje cells. The latter effect does not impair tonic spike firing in the target neurons of inhibitory Purkinje cell projections in the deep cerebellar nuclei, but lowers the Purkinje cell signal-to-noise ratio, thus reducing the PF readout. These observations suggest that intrinsic plasticity accompanies LTP of active PF synapses, while it reduces at weaker, nonpotentiated synapses the probability for subsequent potentiation and lowers the impact on the Purkinje cell output.

Purkinje Cell NMDA Receptors Assume a Key Role in Synaptic Gain Control in the Mature Cerebellum

A classic view in cerebellar physiology holds that Purkinje cells do not express functional NMDA receptors and that, therefore, postsynaptic NMDA receptors are not involved in the induction of long-term depression (LTD) at parallel fiber (PF) to Purkinje cell synapses. Recently, it has been demonstrated that functional NMDA receptors are postsynaptically expressed at climbing fiber (CF) to Purkinje cell synapses in mice, reaching full expression levels at ∼2 months after birth. Here, we show that in the mature mouse cerebellum LTD (induced by paired PF and CF activation), but not long-term potentiation (LTP; PF stimulation alone) at PF to Purkinje cell synapses is blocked by bath application of the NMDA receptor antagonist D-2-amino-5-phosphonovaleric acid (D-APV). A blockade of LTD, but not LTP, was also observed when the noncompetitive NMDA channel blocker MK-801 was added to the patch-pipette saline, suggesting that postsynaptically expressed NMDA receptors are required for LTD induction. Using confocal calcium imaging, we show that CF-evoked calcium transients in dendritic spines are reduced in the presence of D-APV. This observation confirms that NMDA receptor signaling occurs at CF synapses and suggests that NMDA receptor-mediated calcium transients at the CF input site might contribute to LTD induction. Finally, we performed dendritic patch-clamp recordings from rat Purkinje cells. Dendritically recorded CF responses were reduced when D-APV was bath applied. Together, these data suggest that the late developmental expression of postsynaptic NMDA receptors at CF synapses onto Purkinje cells is associated with a switch toward an NMDA receptor-dependent LTD induction mechanism.

Similarity of Visual Selectivity among Clonally Related Neurons in Visual Cortex

Neurons in rodent visual cortex are organized in a salt-and-pepper fashion for orientation selectivity, but it is still unknown how this functional architecture develops. A recent study reported that the progeny of single cortical progenitor cells are preferentially connected in the postnatal cortex. If these neurons acquire similar selectivity through their connections, a salt-and-pepper organization may be generated, because neurons derived from different progenitors are intermingled in rodents. Here we investigated whether clonally related cells have similar preferred orientation by using a transgenic mouse, which labels all the progeny of single cortical progenitor cells. We found that preferred orientations of clonally related cells are similar to each other, suggesting that cell lineage is involved in the development of response selectivity of neurons in the cortex. However, not all clonally related cells share response selectivity, suggesting that cell lineage is not the only determinant of response selectivity.

Oscillating Purkinje Neuron Activity Causing Involuntary Eye Movement in a Mutant Mouse Deficient in the Glutamate Receptor δ2 Subunit

How failures in regulation of synaptic transmission in the mammalian CNS affect neuronal activity and disturb motor coordination is addressed. The mutant mouse deficient in the glutamate receptor δ2 subunit, specifically expressed in cerebellar Purkinje neurons, has defects in synaptic regulations such as synaptic plasticity, stabilization, and elimination of synaptic connections and shows failures in motor coordination and learning. In this study, the cause of motor discoordination of the δ2 mutant mouse was analyzed by comparing its motor control ability with those of the wild-type mouse and the lurcher mutant mouse, which loses all Purkinje neurons, the sole output neurons in the cerebellar cortex. Unexpectedly, the δ2 mutant mouse showed severer motor discoordination than the lurcher mouse without any cerebellar cortical outputs. The δ2 mutant mouse showed involuntary spontaneous eye movement with characteristic 10 Hz oscillation, which disappeared by ablation of the cerebellar flocculus, suggesting that the δ2 mutant cerebellar cortex outputs an abnormal signal. In vivo extracellular recordings of neuronal activity revealed that Purkinje neurons tended to fire clustered action potentials and complex spikes at ∼10 Hz in the δ2 mutant mouse. A whole-cell patch-clamp recording from Purkinje neurons in cerebellar slices indicated that the clustered action potentials could be induced by climbing fiber activation. Taken together, our results suggest that the δ2 subunit deficiency produces the oscillating activity in Purkinje neurons by enhancing climbing fiber inputs, causing surplus movement and affecting motor control worse than no signal at all.

Climbing Fiber Signaling and Cerebellar Gain Control

The physiology of climbing fiber signals in cerebellar Purkinje cells has been studied since the early days of electrophysiology. Both the climbing fiber-evoked complex spike and the role of climbing fiber activity in the induction of long-term depression (LTD) at parallel fiber-Purkinje cell synapses have become hallmark features of cerebellar physiology. However, the key role of climbing fiber signaling in cerebellar motor learning has been challenged by recent reports of forms of synaptic and non-synaptic plasticity in the cerebellar cortex that do not involve climbing fiber activity, but might well play a role in cerebellar learning. Moreover, cerebellar LTD does not seem to strictly require climbing fiber activity. These observations make it necessary to re-evaluate the role of climbing fiber signaling in cerebellar function. Here, we argue that climbing fiber signaling is about adjusting relative probabilities for the induction of LTD and long-term potentiation (LTP) at parallel fiber synapses. Complex spike-associated, dendritic calcium transients control postsynaptic LTD and LTP induction. High calcium transients, provided by complex spike activity, do not only favor postsynaptic LTD induction, but simultaneously trigger retrograde cannabinoid signaling, which blocks the induction of presynaptic LTP. Plasticity of the climbing fiber input itself provides additional means to fine-tune complex spike associated calcium signaling and thus to adjust the gain of heterosynaptic climbing fiber control. In addition to dendritic calcium transients, climbing fiber activity leads to the release of the neuropeptide corticotropin-releasing factor (CRF), which facilitates LTD induction at both parallel fiber and climbing fiber synapses.

SK2 Channel Modulation Contributes to Compartment-Specific Dendritic Plasticity in Cerebellar Purkinje Cells

Small-conductance Ca(2+)-activated K(+) channels (SK channels) modulate excitability and curtail excitatory postsynaptic potentials (EPSPs) in neuronal dendrites. Here, we demonstrate long-lasting plasticity of intrinsic excitability (IE) in dendrites that results from changes in the gain of this regulatory mechanism. Using dendritic patch-clamp recordings from rat cerebellar Purkinje cells, we find that somatic depolarization or parallel fiber (PF) burst stimulation induce long-term amplification of synaptic responses to climbing fiber (CF) or PF stimulation and enhance the amplitude of passively propagated sodium spikes. Dendritic plasticity is mimicked and occluded by the SK channel blocker apamin and is absent in Purkinje cells from SK2 null mice. Triple-patch recordings from two dendritic sites and the soma and confocal calcium imaging studies show that local stimulation limits dendritic plasticity to the activated compartment of the dendrite. This plasticity mechanism allows Purkinje cells to adjust the SK2-mediated control of dendritic excitability in an activity-dependent manner.

Enhancement of Both Long-Term Depression Induction and Optokinetic Response Adaptation in Mice Lacking Delphilin

In the cerebellum, Delphilin is expressed selectively in Purkinje cells (PCs) and is localized exclusively at parallel fiber (PF) synapses, where it interacts with glutamate receptor (GluR) δ2 that is essential for long-term depression (LTD), motor learning and cerebellar wiring. Delphilin ablation exerted little effect on the synaptic localization of GluRδ2. There were no detectable abnormalities in cerebellar histology, PC cytology and PC synapse formation in contrast to GluRδ2 mutant mice. However, LTD induction was facilitated at PF-PC synapses in Delphilin mutant mice. Intracellular Ca2+ required for the induction of LTD appeared to be reduced in the mutant mice, while Ca2+ influx through voltage-gated Ca2+ channels and metabotropic GluR1-mediated slow synaptic response were similar between wild-type and mutant mice. We further showed that the gain-increase adaptation of the optokinetic response (OKR) was enhanced in the mutant mice. These findings are compatible with the idea that LTD induction at PF-PC synapses is a crucial rate-limiting step in OKR gain-increase adaptation, a simple form of motor learning. As exemplified in this study, enhancing synaptic plasticity at a specific synaptic site of a neural network is a useful approach to understanding the roles of multiple plasticity mechanisms at various cerebellar synapses in motor control and learning.

Bidirectional plasticity at developing climbing fiber–Purkinje neuron synapses

Climbing fibers provide one of the two major excitatory inputs to the cerebellar cortex. In an immature animal, several climbing fibers form synapses with one Purkinje neuron. During postnatal development most climbing fiber innervations with a Purkinje neuron are eliminated and only one strong fiber remains. Previous studies suggested that this pruning of surplus climbing fiber innervations depends on the neuronal activity. We hypothesized that synaptic plasticity might play a role in the maturation and refinement of such a climbing fiber projection pattern, and examined the plasticity properties of synapses between postnatal days 5 and 9 in mice. We found that a 5 Hz conditioning stimulation of climbing fibers forming relatively strong synapses with a Purkinje neuron induced long‐term potentiation of the transmission accompanied by a decrease in the paired‐pulse ratio of excitatory postsynaptic current amplitudes. This was suggestive of an increased probability of presynaptic release. However, the conditioning stimulation of climbing fibers forming relatively weak synapses induced long‐term depression and tended to increase the paired‐pulse ratio. Thus, the direction of plasticity appears to be determined by the strength of synaptic connection. Long‐term depression occurred only in the conditioned climbing fiber, whereas long‐term potentiation spread to unconditioned climbing fibers. A postsynaptic increase in the intracellular Ca2+ concentration was required for long‐term potentiation but not for long‐term depression. These results reveal the existence of novel presynaptic plasticity at immature climbing fiber–Purkinje cell synapses, which may contribute to the maturation and refinement of the climbing fiber projection pattern.

Activity-Dependent Plasticity of Spike Pauses in Cerebellar Purkinje Cells

The plasticity of intrinsic excitability has been described in several types of neurons, but the significance of non-synaptic mechanisms in brain plasticity and learning remains elusive. Cerebellar Purkinje cells are inhibitory neurons that spontaneously fire action potentials at high frequencies and regulate activity in their target cells in the cerebellar nuclei by generating a characteristic spike burst-pause sequence upon synaptic activation. Using patch-clamp recordings from mouse Purkinje cells, we find that depolarization-triggered intrinsic plasticity enhances spike firing and shortens the duration of spike pauses. Pause plasticity is absent from mice lacking SK2-type potassium channels (SK2(-/-) mice) and in occlusion experiments using the SK channel blocker apamin, while apamin wash-in mimics pause reduction. Our findings demonstrate that spike pauses can be regulated through an activity-dependent, exclusively non-synaptic, SK2 channel-dependent mechanism and suggest that pause plasticity-by altering the Purkinje cell output-may be crucial to cerebellar information storage and learning.

Enhanced Inhibitory Synaptic Transmission in the Cerebellar Molecular Layer of the GluRδ2 Knock-Out Mouse

A novel ionotropic glutamate receptor subunit δ2 (GluRδ2), which is specifically expressed in cerebellar Purkinje neurons (PNs), is implicated in the induction of long-term depression. Mutant mice deficient in GluRδ2 (δ2-/-) have abnormal cerebellar synaptic organization and impaired motor coordination and learning. Previous in vivo extracellular recordings inδ2-/- revealed that PN activity distinct from that in wild-type (WT) mice is attributable to enhanced climbing fiber activity. Here, we report that GABAergic synaptic transmission was enhanced in the molecular layer of the cerebellar cortex in δ2-/-. Optical recordings in cerebellar slice preparations indicated that application of bicuculline, a GABAA receptor antagonist, increased the amplitude and area of excitation propagation more in δ2-/- than in WT. Whole-cell patch-clamp recordings from PNs demonstrated that miniature IPSC (mIPSC) amplitude were larger in δ2-/- than in WT. Also, rebound potentiation (RP), a type of long-lasting inhibitory synaptic potentiation inducible by postsynaptic depolarization of PNs in WT, was not induced in slices prepared from δ2-/-. In contrast, RP was induced in cultured PNs prepared from δ2-/-. Pharmacologic activation of climbing fibers in WT in vivo increased mIPSC amplitudes in PNs and prevented RP induction. These results suggest that enhanced climbing fiber activity in δ2-/- potentiates IPSC amplitudes in PNs through RP in vivo, resulting in the prevention of additional RP induction.