Cerebellar guidance of premotor network development and sensorimotor learning.
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Single unit and imaging studies have shown that the cerebellum is especially active during the acquisition phase of certain motor and cognitive tasks. These data are consistent with the hypothesis that particular sensorimotor procedures are acquired and stored in the cerebellar cortex and that this knowledge can then be exported to the cerebral cortex and premotor networks for more efficient execution. In this article we present a model to illustrate how the cerebellar cortex might guide the development of cortical-cerebellar network connections and how a similar mechanism operating in the adult could mediate the exportation of sensorimotor knowledge from the cerebellum to the motor cortex. The model consists of a three-layered recurrent network representing the cerebello-thalamocortical-ponto-cerebellar limb premotor network. The cerebellar cortex is not explicitly modeled. Our simulations show that Hebbian learning combined with weight normalization allows the emergence of reciprocal and modular structure in the limb premotor network. Reciprocal connections allow activity to reverberate around specific loops. Modularity organizes the connections into specific channels. Furthermore, we show that cerebellar learning can be exported to motor cortex through these modular and reciprocal premotor circuits. In particular, we simulate developmental alignment of visuomotor relations and their realignment as a consequence of prism exposure. The exportation of sensorimotor knowledge from the cerebellum to the motor cortex may allow faster and more efficient execution of learned motor responses. (+info)
Convergent but temporally separated inputs to lateral amygdala neurons from the auditory thalamus and auditory cortex use different postsynaptic receptors: in vivo intracellular and extracellular recordings in fear conditioning pathways.
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The lateral nucleus of the amygdala (LA), a key component of the fear conditioning circuitry, receives a rapid but relatively impoverished auditory input from the auditory thalamus and a slower but richer input from the auditory cortex. We examined in urethane anesthetized rats whether individual cells in the LA receive convergent inputs from these two areas, and whether different postsynaptic receptors contribute to the temporally separated excitations over the two pathways. With both extracellular and intracellular recordings, individual cells could be activated by stimulation of each pathway. In extracellular recordings iontophoretic application of the N-methyl-D-aspartate (NMDA) receptor antagonist APV and the L-alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) receptor antagonist CNQX demonstrated that synaptic transmission in both pathways depends on AMPA receptors, whereas transmission in the thalamic pathway also depends on the involvement of NMDA receptors. The involvement of NMDA receptors in synaptic activation of the LA from the thalamus but not the cortex was confirmed in intracellular recordings using systemic injections of the NMDA antagonist MK-801. The slow time course of NMDA currents could provide LA cells with a mechanism to integrate the inputs arriving rapidly from the thalamus and somewhat later from the cortex, thus allowing the LA to integrate signals in the two pathways during the acquisition and expression of conditioned fear reactions. (+info)
Group III metabotropic glutamate receptors control corticothalamic synaptic transmission in the rat thalamus in vitro.
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1. Corticothalamic (CT) EPSPs evoked at <= 0.1 Hz were recorded from thalamocortical neurones in the rat dorsal lateral geniculate nucleus in vitro, with both GABAA and GABAB receptors blocked. 2. The group III metabotropic glutamate (mGlu) receptor agonists L-2-amino-4-phosphono-butyric acid (L-AP4) and O-phospho-L-serine (L-SOP) both caused a concentration-dependent depression of the CT EPSP. The maximum depression and EC50 values for these effects were 64.4 +/- 3.8 % and 88.0 +/- 24.7 microM for L-AP4, and 42.0 +/- 2.5 % and 958 +/- 492 microM for L-SOP, respectively (means +/- s.e.m.). Neither agonist had any effect on membrane potential or input resistance. 3. The depression of the CT EPSP caused by L-AP4 was reversed using the group III antagonist (S)-2-amino-2-methyl-4-phosphonobutanoic acid (MAP4, 1 mM), and the group II/III antagonist LY341495 (3 microM), but not using the group II antagonist (2S)-alpha-ethylglutamic acid (300 microM). The potencies of L-AP4, L-SOP and LY341495 indicate that this action of L-AP4 is mediated via mGlu7 and mGlu8 and not mGlu4 receptors. 4. Neither MAP4 nor LY341495 had any effect on the CT EPSPs evoked by 10 Hz trains of five stimuli, indicating the lack of endogenous activation of group III mGlu receptors in the thalamus during short bursts of cortical input. However, the magnitude of the depression caused by L-AP4 indicates that any physiological activation of group III mGlu receptors would have a profound effect on the CT input to the thalamus, and hence cortical control of thalamic function. (+info)
Modulation of the hyperpolarization-activated cation current of rat thalamic relay neurones by intracellular pH.
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1. Properties of the hyperpolarization-activated cation current (Ih) were investigated in thalamocortical neurones of an in vitro slice preparation of the rat ventrobasal thalamic complex (VB) before and during changes of pipette pH (pHp), intracellular pH (pHi) and bath pH (pHb) using the whole-cell patch-clamp technique and fluorescence ratio imaging of the pH indicator 2',7'-bis(carboxyethyl)-5(and -6)-carboxyfluorescein (BCECF). 2. Recording of Ih with predefined pHp revealed significant shifts in the voltage dependence of Ih activation (V ) of 4-5 mV to more positive values for a pHp of 7.5 and 2-3 mV to more negative values for a pHp of 6.7 as compared to control values (pHp = 7.1). 3. Application of the weak acid lactate (20 mM), which produced a slow monophasic intracellular acidification, induced a reversible negative shift of V of up to 3 mV. Application of 20 mM TMA, which caused a distinct intracellular alkalinization, shifted V to 4-5 mV more positive values. 4. In slices bathed in Hepes-buffered saline, no significant pHo dependence of Ih was observed. Changing pHo by altering the extracellular [HCO3-] in the presence of constant pCO2 also revealed no significant pHo dependence of Ih. 5. Rhythmic stimulation of thalamocortical neurones with repetitive depolarizing pulse trains caused an intracellular acidification, which reversibly decreased the amplitude and time course of activation of Ih. 6. The results of the present study indicate that shifts in pHi result in a significant modulation of the gating properties of Ih channels in TC neurones. Through this mechanism activity-dependent shifts in pHi may contribute to the up- and downregulation of Ih. (+info)
Upregulation of the hyperpolarization-activated cation current in rat thalamic relay neurones by acetazolamide.
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1. The effect of inhibition of brain carbonic anhydrase (CA) on the hyperpolarization-activated cation current (Ih) of thalamocortical (TC) neurones of the rat ventrobasal thalamic complex (VB) was investigated in an in vitro slice preparation using the whole-cell patch-clamp technique and fluorescence ratio imaging of the pH indicator 2',7'-bis(carboxyethyl)-5(and -6)-carboxyfluorescein (BCECF). 2. Recording of Ih before and after addition of 0.4-0.8 mM acetazolamide to the bathing fluid revealed a significant shift in the voltage dependence of activation (V ) of 5-7 mV to more positive potentials. 3. Simultaneous recording of Ih and BCECF fluorescence ratio (F420/F495) revealed an increase in Ih amplitude accompanied by an intracellular alkalinization upon application of acetazolamide. The CA inhibitor ethoxyzolamide (EZA, 50 microM) also led to an intracellular alkalinization and a subsequent 4-5 mV positive shift of V of Ih. 4. Acetazolamide and EZA both profoundly slowed the rapid fall of pHi upon switching from Hepes- to CO2/HCO3--buffered superfusate, indicating intracellular CA isoforms in TC neurones. 5. In slices bathed in Hepes-buffered saline, addition of acetazolamide had no effect on the amplitude and time course of activation of Ih, indicating that the action of acetazolamide on Ih was dependent on the presence of HCO3-. 6. Under current-clamp conditions, the neuronal response to hyperpolarizing current pulses in the presence of acetazolamide was decreased as compared to control. This resulted in a strongly reduced ability of TC neurones to produce rebound Ca2+-mediated spikes. 7. The present results implied that in TC neurones acetazolamide led to an intracellular alkalinization which causes, due to its pH sensitivity, an increase in Ih. (+info)
Mechanisms underlying spontaneous oscillation and rhythmic firing in rat subthalamic neurons.
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Subthalamic neurons drive basal ganglia output neurons in resting animals and relay cortical and thalamic activity to the same output neurons during movement. The first objective of this study was to determine the mechanisms underlying the spontaneous activity of subthalamic neurons in vitro and to gain insight into their resting discharge in vivo. The second objective was to determine the response of subthalamic neurons to depolarizing current injection and how intrinsic properties may shape their response to cortical and thalamic inputs during movement. Cell-attached and whole-cell recordings were made from subthalamic neurons in brain slices prepared from 3- to 4-week-old rats. The slow, rhythmic discharge of subthalamic neurons was resistant to blockade of excitatory synaptic transmission indicating that intrinsic currents underlie their spontaneous discharge. A persistent sodium current was the source of current during the depolarizing phase of the oscillation. A powerful afterhyperpolarization following each action potential was sufficient to terminate the depolarization. A long duration component of the spike afterhyperpolarization determined the period of the oscillation and was generated by an apamin-sensitive calcium-activated potassium current. Calcium entry responsible for that current was associated with action potentials. Subthalamic neurons exhibited a sigmoidal frequency-current relationship with the steeper portion starting at approximately 30-40 Hz. This property makes subthalamic neurons more sensitive to input at high firing rates associated with movement than at low rates associated with rest. We propose that the subthreshold persistent sodium current overcomes calcium activated potassium current which accumulates during high frequency firing and underlies the enhanced sensitivity to current >30 Hz. (+info)
Growth-associated protein 43 is located in type I corticothalamic terminals in the cat visual thalamus.
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Growth-associated protein 43 (GAP 43) is a presynaptic protein that has been proposed to be involved in synaptic plasticity. To determine the location of GAP 43 within the synaptic circuitry of the thalamus, immunocytochemical staining for GAP 43 was examined in a relay nucleus, the dorsal lateral geniculate nucleus (dLGN), and two association nuclei, the pulvinar nucleus and the lateral subdivision of the lateral posterior (LP) nucleus. In the dLGN, moderate neuropil staining was seen in the A laminae, and denser staining was found in the interlaminar zones and the C laminae. Uniform dense staining of the neuropil was found in both the pulvinar and LP nuclei. At the ultrastructural level, the GAP 43 staining was restricted to small-diameter myelinated axons, thin unmyelinated fibers, and small terminals that contained densely packed round vesicles (RS profiles) and made asymmetric synaptic contacts with small-caliber dendrites in the extraglomerular neuropil. The distribution of immunocytochemical label within the visual thalamus suggests that GAP 43 is confined to type I corticothalamic terminals and axons that originate from extrastriate cortical areas. These results also suggest that in both relay and association nuclei GAP 43 may be used to augment the cortical control of thalamic activity. In addition, these results underscore the distinction between the small type I corticothalamic terminals, which appear to contain GAP 43 throughout the visual thalamus, and the large type II corticothalamic terminals that, like the type II retinal terminals in the dLGN, do not contain GAP 43. (+info)
Pain and functional imaging.
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Functional neuroimaging has fundamentally changed our knowledge about the cerebral representation of pain. For the first time it has been possible to delineate the functional anatomy of different aspects of pain in the medial and lateral pain systems in the brain. The rapid developments in imaging methods over the past years have led to a consensus in the description of the central pain responses between different studies and also to a definition of a central pain matrix with specialized subfunctions in man. In the near future we will see studies where a systems perspective allows for a better understanding of the regulatory mechanisms in the higher-order frontal and parietal cortices. Also, pending the development of experimental paradigms, the functional anatomy of the emotional aspects of pain will become better known. (+info)