Stephen T. Kitai

Up and Down States in Striatal Medium Spiny Neurons Simultaneously Recorded with Spontaneous Activity in Fast-Spiking Interneurons Studied in Cortex–Striatum–Substantia Nigra Organotypic Cultures

In vivo intracellular spontaneous activity in striatal medium spiny (MS) projection neurons is characterized by “up” and “down” states. How this type of activity relates to the neuronal activity of striatal fast-spiking (FS) interneurons was examined in the presence of nigral and cortical inputs using cortex–striatum–substantia nigra organotypic cultures grown for 45 ± 4 d. The nigrostriatal projection was confirmed by tyrosine hydroxylase immunoreactivity. Corticostriatal (CS) projection neurons, striatal MS neurons, and FS neurons were intracellularly recorded and morphologically and electrophysiologically characterized. Intracellular spontaneous activity in the cultures consisted of intermittent depolarized periods of 0.5–1 sec duration. Spontaneous depolarizations in MS neurons were restricted to a narrow membrane potential range (up state) during which they occasionally fired single spikes. These up states were completely blocked by the glutamate antagonist CNQX. In FS interneurons, depolarized periods were characterized by large membrane potential fluctuations that occupied a wide range between rest and spike threshold. Also, FS interneurons spontaneously fired at much higher rates than did MS neurons. Simultaneous intracellular recordings established that during spontaneous depolarizations MS neurons and FS interneurons displayed correlated subthreshold neuronal activity in the low frequency range. These results indicate that (1) the CS projection neurons, striatal MS neurons, and FS interneurons grown in cortex–striatum–substantia nigra organotypic cultures show morphological and electrophysiological characteristics similar to those seen in vivo; (2) striatal MS neurons but not FS interneurons show an up state; (3) striatal MS neurons and FS interneurons receive common, presumably cortical inputs in the low frequency range. Our results support the view that the cortex provides a feedforward inhibition of MS neuron activity during the up state via FS interneurons.

Differential Expression of ErbB3 and ErbB4 Neuregulin Receptors in Dopamine Neurons and Forebrain Areas of the Adult Rat

Neuregulins have been shown to play an important role in the development of the central nervous system, but their function in adult tissues is still unclear. We investigated the expression of the neuregulin receptors erbB3 and erbB4 in the adult rat brain by in situ hybridization histochemistry. Areas with considerable expression of erbB4 receptor mRNA include cortex, amygdala, hippocampus, medial habenula, reticular thalamic nucleus, several hypothalamic nuclei, subthalamic nucleus, substantia nigra pars compacta, and ventral tegmental area. Immunostaining for tyrosine hydroxylase and dopamine depletion by 6-hydroxydopamine indicate that erbB4 is expressed in dopamine neurons in the latter two nuclei. Substantial erbB4 expression is also present in clusters of cells along the ventral and medial border of the striatum/nucleus accumbens and in the subependymal zone along the lateral and olfactory ventricles (rostral migratory stream), suggesting a role for neuregulins in adult cell proliferation. In contrast, erbB3 mRNA is mostly expressed in white matter throughout the brain and in the ependyma of the ventral half of the third ventricle (tanycytes). These results demonstrate that expression of erbB3 and erbB4 receptors is widespread in the adult rat brain and suggest a function for neuregulins into adulthood.

Intracellular analysis in vivo of different barosensitive bulbospinal neurons in the rat rostral ventrolateral medulla

Neurons located in the rostral ventrolateral medulla (RVLM) with projections to the intermediolateral column (IML) in the spinal cord were electrophysiologically characterized and anatomically identified using an intracellular recording technique in vivo. A group of spontaneously active neurons was antidromically activated by electrical stimulation of the IML in the thoracic spinal cord (T2-T3 level). The axonal conduction velocities ranged from 1.5 m/sec to 11.0 m/sec; mean value, 5.5 +/- 2.6 m/sec (+/- SD). The firing pattern and changes in membrane potential in relation to the cardiac cycle were investigated in these bulbospinal neurons. A first group discharged action potentials with higher frequency at the end of the diastolic/beginning of the systolic period. The average of the neuronal membrane potentials demonstrated depolarizing potentials at the end of the diastolic/beginning of the systolic period. These depolarizing potentials increased in magnitude when the neurons were hyperpolarized. Therefore, they were characterized as EPSPs. The baroreceptor reflex activation produced by the increase in systemic arterial pressure following intravenous injection of phenylephrine elicited hyperpolarization, a decrease in the rate of discharge, and an increase in the membrane input resistance, suggesting that a disfacilitatory effect was produced by the activation of baroreceptor inputs on these bulbospinal neurons. Conversely, the inactivation of the baroreceptor reflex by intravenous injection of sodium nitroprusside produced depolarization and an increase in the firing rate. These neurons were characterized as baroreceptor-sensitive type I neurons. A second group of bulbospinal neuron in the RVLM was differentiated from the first group because it demonstrated a decrease in the frequency of discharge at the end of the diastolic/beginning of the systolic period. The average of the membrane potentials showed hyperpolarizing potentials that decreased in magnitude when the neuron was hyperpolarized. These hyperpolarizing potentials occurred at the end of the diastolic/beginning of the systolic period and were reversed in polarity after intracellular injections of chloride ions for several minutes. Therefore, these potentials were characterized as chloride- dependent IPSPs locked to the cardiac cycle. In some of these neurons, the electrical stimulation of the IML produced, in addition to the antidromic action potential, a monosynaptic EPSP with a shorter latency. Based on these unique characteristics, these neurons were defined as barosensitive type II neurons. During constant baroreceptor inactivation achieved by the hypotension produced by intravenous infusions of sodium nitroprusside, the pattern of discharge of barosensitive type II neurons became very regular, and the IPSPs locked to the cardiac cycle were absent.(ABSTRACT TRUNCATED AT 400 WORDS)

Unilateral striatal dopamine depletion: time‐dependent effects on cortical function and behavioural correlates

Previously, we showed that unilateral blockade of D1 dopamine receptors in the striatum inhibits immediate‐early gene expression bilaterally throughout large parts of the cortex, including sensory‐evoked expression in the barrel cortex. To further investigate this dopamine regulation of cortical function, we examined the effects of dopamine depletion on cortical gene regulation and behavioural correlates. Two days after unilateral infusion of 6‐hydroxydopamine into the midbrain, rats displayed a (to some degree) bilateral reduction in cortical zif 268 expression that was more pronounced on the lesioned side. This decrease was found across motor, somatosensory, insular and piriform, but not cingulate, cortex, similar to the effects of blockade of striatal D1 receptors. Furthermore, whisker stimulation‐evoked c‐fos and zif 268 expression in the barrel cortex ipsilateral to the lesion was also attenuated by acute dopamine depletion. These cortical deficits were accompanied by a breakdown of spontaneous behaviours in an open‐field test. In contrast, 21u2003days after dopamine depletion, both basal and sensory‐evoked gene expression in the cortex were near‐normal. This cortical recovery was paralleled by recovery in locomotion and in sensory‐guided behaviour (scanning) related to the hemisphere contralateral to the lesion, but not in scanning by the dopamine‐depleted hemisphere. Our results suggest that striatal dopamine exerts a widespread facilitatory influence on cortical function that is necessary, but not sufficient, for normal behaviour. Moreover, the mechanisms mediating this cortical facilitation appear to be subject to substantial neuroplasticity after dopamine perturbation.

Morphological organization of the globus pallidus-subthalamic nucleus system studied in organotypic cultures

The morphological organization of the globus pallidus (GP), the subthalamic nucleus (STN), and the pallidosubthalamic projection was studied in organotypic cultures. Coronal slices from the GP, the STN, the striatum (CPu), and the cortex (Cx) were taken from the rat after postnatal days 0–2 and grown for 2 or 5–6 weeks. For analysis, immunocytochemistry against glutamate (GLU), parvalbumin (PV), and calretinin (CR) was combined with confocal microscopy.

Dopaminergic regulation of striatal efferent pathways

In the past year there has been a growing debate about the distribution of dopamine receptors in striatal efferent pathways. As is often the case, different approaches lead to different perspectives. Nevertheless, the available data can be reconciled with a model in which D1 and D2 dopamine receptors are segregated in the distal dendrites and axonal terminal fields of striatonigral and striatopallidal neurons, but intermingled in the soma and proximal dendrites.

Morphological study of the tegmental pedunculopontine nucleus, substantia nigra and subthalamic nucleus, and their interconnections in rat organotypic culture

The morphological organization of the tegmental pedunculopontine nucleus, midbrain extrapyramidal area, substantia nigra and subthalamic nucleus and their interrelationships were studied in rat organotypic culture using immunohistochemistry and NADPH-diaphorase histochemistry. Three coronal sections, one containing the tegmental pedunculopontine nucleus/midbrain extrapyramidal area, another with the substantia nigra and the third with the subthalamic nucleus, were obtained from postnatal 1–2-day-old rats. These sections were co-cultured for 3–4 weeks using the roller-tube technique. In the tegmental pedunculopontine nucleus/midbrain extrapyramidal area, the distribution pattern of cholinergic neurons was similar to that found in the in vivostudy. We could, therefore, identify the subdivisions of the tegmental pedunculopontine nucleus (i.e., pars compacta and pars dissipata) and the midbrain extrapyramidal area. As in the in vivosituation, glutamate immunoreactive neurons were also located in these areas. Approximately 10% of NADPH-diaphorase positive neurons in the tegmental pedunculopontine nucleus, were glutamate immunoreactive. In the substantia nigra, as in the in vivo, tyrosine hydroxylase immunoreactive (putative dopaminergic) neurons were identified predominantly in the substantia nigra pars compacta, and parvalbumin immunoreactive neurons (putative GABAergic) mainly in the substantia nigra pars reticulata. The subthalamic nucleus was ladened with glutamate immunoreactive neurons. NADPH-diaphorase stained axons originating from the tegmental pedunculopontine nucleus were traced into the substantia nigra and subthalamic nucleus. They were often in close apposition to tyrosine hydroxylase immunoreactive neurons in the substantia nigra. Parvalbumin immunoreactive fibers from the substantia nigra projected heavily to the midbrain extrapyramidal area, but only sparsely to the tegmental pedunculopontine nucleus and the subthalamic nucleus. These findings indicate that the tegmental pedunculopontine nucleus/midbrain extrapyramidal area, substantia nigra and subthalamic nucleus in the organotypic culture have retained a basic morphological organization and connectivity similar to those seen in the in vivosituation. Therefore, this preparation could be a useful model to conduct further studies to investigate functional circuits among the structures represented.

The morphology and divergent axonal organization of midbrain raphe projection neurons in the rat

The morphology of dorsal raphe neurons was examined using intracellular injections of horseradish peroxidase (HRP) and the Golgi technique. Light microscopic examination of HRP-labeled projection neurons revealed a neuron type with radiating, poorly branched and sparsely spined dendrites and terminal dendritic thickets. The stem axon of these neurons left the nucleus ventrally but gave off a beaded collateral while still within the parent cells dendritic domain. Somatodendritic morphology from Golgi-Kopsch stained material coincided with intracellular HRP findings and the dorsal raphe may consist of varieties of one basic morphological type of neuron. Intracellular recordings made during the HRP injection experiments confirmed that stimulation of the ventral medial tegmentum elicited an antidromic action potential and an inhibitory postsynaptic potential in dorsal raphe projection neurons. The order of axonal projections arising from the midbrain raphe nuclei was examined using a double retrograde axonal tracing technique. After paired HRP and [3H] wheat germ agglutinin injections within certain projection targets of the dorsal and median raphe neurons (caudate-putamen, amygdala, hippocampus, substantia nigra and locus coeruleus), each target structure was found to have its own unique representation within a topographically distinct portion of one or more of the raphe subgroups. Neurons projecting to the caudate-putamen and substantia nigra occupied rather rostral portions. Neurons projecting to the hippocampus and locus coeruleus resided more caudally. Neurons projecting to the amygdala were situated intermediately. Overall, rostrocaudal topography in the intranuclear distributions of raphe projection neurons resulted in the formation of complex overlap zones where collateralized neurons always resided.

Intracellular Labeling and Immunocytochemistry

Since its introduction in 1976 (Cullheim and Kellerth, 1976; Jankowska et al., 1976; Kitai et al., 1976; Light and Durkovic, 1976; Snow et al., 1976), the method of intracellular injection of horseradish peroxidase (HRP) has established itself as an enormously productive tool for neurobiology (Kitai and Bishop, 1981; Kitai and Wilson, 1982). The fundamental advantage of the technique is that it allows direct correspondence between cellular physiology and morphology to be established. First, as a physiological tool, the HRP-filled microelectrode is suitable for the analysis of any neurophysiological property of a neuron that can be assayed by intracellular recording. Second, as a morphological tool, intracellular iontophoresis of HRP fills and labels the entire extent of a neuron, including soma, dendrites, dendritic specializations such as spines, and as much of the axon, axonal collaterals, and terminals as survival time permits. The morphological rendition of the HRP-filled neuron revealed by enzyme histochemistry is equal to or better than the results of the very best Golgi stains.

Morphological and Electrophysiological Studies of Substantia Nigra, Tegmental Pedunculopontine Nucleus, and Subthalamus in Organotypic Co-Culture

Recently we incorporated an organotypic culture method in our basal ganglia research. In our preparation, we were successful in co-culturing more than two structures of interest1–3. This in vitro organotypic preparation combines the advantage of in vitro slice preparation for ease of intracellular sharp or patch recording under improved controlled experimental chemical environment with the in vivo preparation in which the structure of interest is not isolated from the source of their major afferents. In this report, we would like to present a triple culture preparation consisting of the tegmental pedunculopontine nucleus (PPN), the subthalamic nucleus (STN) and the substantia nigra (SN).