ABSTRACT
Membrane potential oscillations of thalamocortical (TC) neurons are believed to be involved in the generation and maintenance of brain rhythms that underlie global physiological and pathological brain states. These membrane potential oscillations depend on the synaptic interactions of TC neurons and their intrinsic electrical properties. These oscillations may be also shaped by increased output responses at a preferred frequency, known as intrinsic neuronal resonance. Here, we combine electrophysiological recordings in mouse brain slices, modern pharmacological tools, dynamic clamp, and computational modeling to study the ionic mechanisms that generate and modulate TC neuron resonance. We confirm findings of pioneering studies showing that most TC neurons display resonance that results from the interaction of the slow inactivation of the low-threshold calcium current IT with the passive properties of the membrane. We also show that the hyperpolarization-activated cationic current Ih is not involved in the generation of resonance; instead it plays a minor role in the stabilization of TC neuron impedance magnitude due to its large contribution to the steady conductance. More importantly, we also demonstrate that TC neuron resonance is amplified by the inward rectifier potassium current IKir by a mechanism that hinges on its strong voltage-dependent inward rectification (i.e., a negative slope conductance region). Accumulating evidence indicate that the ion channels that control the oscillatory behavior of TC neurons participate in pathophysiological processes. Results presented here points to IKir as a new potential target for therapeutic intervention.NEW & NOTEWORTHY Our study expands the repertoire of ionic mechanisms known to be involved in the generation and control of resonance and provides the first experimental proof of previous theoretical predictions on resonance amplification mediated by regenerative hyperpolarizing currents. In thalamocortical neurons, we confirmed that the calcium current IT generates resonance, determined that the large steady conductance of the cationic current Ih curtails resonance, and demonstrated that the inward rectifier potassium current IKir amplifies resonance.
Subject(s)
Action Potentials , Cerebral Cortex/physiology , Neurons/physiology , Potassium Channels, Inwardly Rectifying/metabolism , Thalamus/physiology , Animals , Calcium Channels/metabolism , Cerebral Cortex/cytology , Cerebral Cortex/metabolism , Mice , Models, Neurological , Neurons/metabolism , Sodium Channels/metabolism , Thalamus/cytology , Thalamus/metabolismABSTRACT
The posterior parietal cortex (PPC) is a central hub for the primate forebrain networks that control skilled manual behavior, including tool use. Here, we quantified and compared the sources of thalamic input to electrophysiologically-identified hand/forearm-related regions of several PPC areas, namely areas 5v, AIP, PFG, and PF, of the capuchin monkey (Sapajus sp). We found that these areas receive most of their thalamic connections from the Anterior Pulvinar (PuA), Lateral Posterior (LP) and Medial Pulvinar (PuM) nuclei. Each PPC area receives a specific combination of projections from these nuclei, and fewer additional projections from other nuclei. Moreover, retrograde labeling of the cells innervating different PPC areas revealed substantial intermingling of these cells within the thalamus. Differences in thalamic input may contribute to the different functional properties displayed by the PPC areas. Furthermore, the observed innervation of functionally-related PPC domains from partly intermingled thalamic cell populations accords with the notion that higher-order thalamic inputs may dynamically regulate functional connectivity between cortical areas.
Subject(s)
Motor Activity/physiology , Neural Pathways/physiology , Parietal Lobe/physiology , Thalamus/physiology , Tool Use Behavior/physiology , Animals , Brain Mapping , Cebus , Female , Forelimb/innervation , Forelimb/physiology , Male , Neural Pathways/cytology , Parietal Lobe/cytology , Thalamus/cytologyABSTRACT
Fear memories allow animals to avoid danger, thereby increasing their chances of survival. Fear memories can be retrieved long after learning, but little is known about how retrieval circuits change with time. Here we show that the dorsal midline thalamus of rats is required for the retrieval of auditory conditioned fear at late (24 hours, 7 days, 28 days), but not early (0.5 hours, 6 hours) time points after learning. Consistent with this, the paraventricular nucleus of the thalamus (PVT), a subregion of the dorsal midline thalamus, showed increased c-Fos expression only at late time points, indicating that the PVT is gradually recruited for fear retrieval. Accordingly, the conditioned tone responses of PVT neurons increased with time after training. The prelimbic (PL) prefrontal cortex, which is necessary for fear retrieval, sends dense projections to the PVT. Retrieval at late time points activated PL neurons projecting to the PVT, and optogenetic silencing of these projections impaired retrieval at late, but not early, time points. In contrast, silencing of PL inputs to the basolateral amygdala impaired retrieval at early, but not late, time points, indicating a time-dependent shift in retrieval circuits. Retrieval at late time points also activated PVT neurons projecting to the central nucleus of the amygdala, and silencing these projections at late, but not early, time points induced a persistent attenuation of fear. Thus, the PVT may act as a crucial thalamic node recruited into cortico-amygdalar networks for retrieval and maintenance of long-term fear memories.
Subject(s)
Fear/physiology , Memory/physiology , Neural Pathways/physiology , Amygdala/cytology , Amygdala/physiology , Animals , Conditioning, Psychological/physiology , Male , Neural Pathways/cytology , Neurons/physiology , Optogenetics , Prefrontal Cortex/cytology , Prefrontal Cortex/physiology , Proto-Oncogene Proteins c-fos/metabolism , Rats , Rats, Sprague-Dawley , Thalamus/cytology , Thalamus/physiology , Time FactorsABSTRACT
The dorsal premammillary nucleus (PMd) is thought to play a critical role for the expression of fear responses to environmental threats. We have reported previously that during an encounter with a predator the PMd presents an impressive increase in Fos levels and cell body-specific chemical lesions therein virtually eliminate the expression of escape and freezing responses. In the present study, we carried out a systematic analysis of PMd afferent connections combining anterograde and retrograde tracing methods in the rat. We show that the nucleus receives inputs from several widely distributed areas in the forebrain and, to a much lesser extent, from the brainstem as well. From this information, it seems that the major telencephalic source of input to the PMd is the interfascicular nucleus of the bed nuclei of the stria terminalis. In addition, substantial telencephalic inputs to the nucleus seem to arise from the infralimbic and prelimbic areas, and the lateral septal nucleus. In the diencephalon, massive inputs to the PMd arise from the anterior hypothalamic nucleus, specific parts of the perifornical region, the retinoceptive region of the lateral hypothalamic area, and the anterior and dorsomedial parts of the ventromedial hypothalamic nucleus. In contrast, the ventral tegmental nucleus seems to be the only brainstem site that provides substantial inputs to the PMd. Overall, the present analysis helps to delineate prosencephalic circuits seemingly critical for the organization of innate fear responses to environmental threats, where the PMd presents a major associative role. Furthermore, by means of massive inputs from the ventral tegmental nucleus, the PMd is in a position to integrate information from a neural system involved in spatial working memory, which may be of particular relevance for an effect of attentional mechanisms on the selection of appropriate escape strategies.
Subject(s)
Afferent Pathways/cytology , Fear/physiology , Hypothalamus/cytology , Afferent Pathways/physiology , Animals , Brain Mapping , Brain Stem/cytology , Brain Stem/physiology , Hypothalamus/physiology , Limbic System/cytology , Limbic System/physiology , Male , Memory, Short-Term/physiology , Rats , Rats, Wistar , Septal Nuclei/cytology , Septal Nuclei/physiology , Telencephalon/cytology , Telencephalon/physiology , Thalamus/cytology , Thalamus/physiologyABSTRACT
The distribution of the well-labeled nicotinamide adenine dinucleotide phosphate diaphorase (NADPHd) Type I neurons was evaluated in the isocortex of four mammalian species: the Didelphis opossum, the Monodelphis opossum, the rat and the marmoset. In Didelphis opossum, laminar distribution was examined in tangential and non-tangential sections. The density increases from superficial to deep layers of the gray matter. In rats' tangential sections, infragranular and supragranular layers have higher density than layer IV. Cell density measurements in the visual and the somatosensory cortices were compared in tangential sections from flattened hemispheres of the four species. Somatosensory areas were identified histochemically in rat (barrel fields) and marmoset (S1 and S2/PV). In the opossums, areas S1 and S2/PV were identified by multiunit recording. Except in the rat, primary visual cortex (V1) was labeled histochemically by NADPHd and/or cytochrome oxidase. In the four species, cell density in somatosensory cortex was significantly higher than in visual cortex. Taken together these results demonstrate that NADPHd Type I neurons are not homogeneously distributed in the isocortex of these mammals. In conclusion, the tangential distribution of Type I neurons in the sensory areas examined, but not its laminar distribution, was similar in the four species. Given that rats, marmosets and opossums are distantly related species, and that the latter are considered to have more 'generalized' brains, it is conceivable that this pattern of tangential distribution of Type I neurons is a general feature of mammalian isocortex.
Subject(s)
NADPH Dehydrogenase/analysis , Neurons/enzymology , Somatosensory Cortex/cytology , Visual Cortex/cytology , Afferent Pathways , Animals , Callithrix , Cell Count , Electrophysiology , Neuropil/enzymology , Opossums , Rats , Somatosensory Cortex/physiology , Species Specificity , Thalamus/cytology , Visual Cortex/physiologyABSTRACT
1. Dopamine is known to modulate glutamatergic synaptic transmission in the retina and in several brain regions by activating specific G-protein-coupled receptors. We have examined the possibility of a different type of mechanism for this modulation, one involving direct interaction of dopamine with ionotropic glutamate receptors. 2. Ionic currents induced by fast application of N-methyl-D-aspartate (NMDA) were recorded under whole-cell patch-clamp in cultured striatal, thalamic and hippocampal neurons of the rat and in retinal neurons of the chick. Dopamine at concentrations above 100 microM inhibited the NMDA response in all four neuron types, exhibiting an IC50 of 1.2 mM in hippocampal neurons. The time course of this inhibition was fast, developing in less than 100 ms. 3. The D1 receptor agonist (+)-SKF38393 mimicked the effect of dopamine, with an IC50 of 58.9 microM on the NMDA response, while the enantiomer (-)-SKF38393 was ineffective at 50 microM. However, the D1 antagonist R(+)-SCH23390 did not prevent the inhibitory effect of (+)-SKF38393. 4. The degree of inhibition by dopamine and (+)-SKF38393 depended on transmembrane voltage, increasing 2.7 times with a hyperpolarization of about 80 mV. The voltage-dependent block by dopamine was also observed in the presence of MgCl2 1 mM. 5. Single-channel recordings showed that the open times of NMDA-gated channels were shortened by (+)-SKF38393. 6. These data suggested that the site to which the drugs bound to produce the inhibitory effect was distinct from the classical D1-type dopamine receptor sites, possibly being located inside the NMDA channel pore. It is concluded that dopamine and (+)-SKF38393 are NMDA channel ligands.
Subject(s)
2,3,4,5-Tetrahydro-7,8-dihydroxy-1-phenyl-1H-3-benzazepine/pharmacology , Cardiotonic Agents/pharmacology , Dopamine Agonists/pharmacology , Dopamine/pharmacology , Ion Channels/antagonists & inhibitors , Receptors, N-Methyl-D-Aspartate/antagonists & inhibitors , Receptors, N-Methyl-D-Aspartate/metabolism , Animals , Cells, Cultured , Chick Embryo , Corpus Striatum/cytology , Corpus Striatum/drug effects , Hippocampus/cytology , Hippocampus/drug effects , Ion Channel Gating/drug effects , Ion Channels/physiology , Membrane Potentials/drug effects , N-Methylaspartate/pharmacology , N-Methylaspartate/physiology , Neurons/drug effects , Neurons/physiology , Rats , Rats, Wistar , Receptors, N-Methyl-D-Aspartate/physiology , Retina/cytology , Retina/drug effects , Stereoisomerism , Thalamus/cytology , Thalamus/drug effectsABSTRACT
Cholinergic basal forebrain (CBF ) neurons have been shown to respond in vivo to exogenous administration of NGF. Although neurotrophins and their receptors are widely expressed in the CNS, little data exist for the physiological significance of endogenous neurotrophin signaling in CNS neurons. To test directly whether cortically derived NGF is functionally required for the cholinergic functions mediated by the cerebral cortex, repeated injections of anti-NGF mAbs were locally applied into the insular cortex (IC) of rats. The biochemical results, using an in vivo microdialysis technique, showed a dramatic lack of extracellular release of acetylcholine after high potassium stimulation compared with controls. Furthermore, by using small injections of the neurotracer fluorogold, we found a corresponding disruption in the connectivity between the IC and the CBF. Behavioral experiments showed that the NGF antibodies applied into the IC produced a significant disruption on the acquisition of conditioned taste aversion and inhibitory avoidance learning. However, the same animals were able to recall the taste aversion when the conditioning trial was established before injections of NGF antibodies. Given these results, it seems that cortical cholinergic functions are actively dependent on locally derived NGF in the adult normal brain, and that the cholinergic activity from the CBF is not necessary for recalling aversive stimuli, but is necessary for the acquisition of aversively motivated conditionings.
Subject(s)
Avoidance Learning/physiology , Cholinergic Fibers/physiology , Nerve Growth Factors/pharmacology , Stilbamidines , Age Factors , Animals , Antibodies, Monoclonal/pharmacology , Avoidance Learning/drug effects , Binding, Competitive/immunology , Cholinergic Fibers/drug effects , Conditioning, Psychological/drug effects , Conditioning, Psychological/physiology , Denervation , Fluorescent Dyes , Male , Memory/physiology , Microinjections , Nerve Growth Factors/analysis , Nerve Growth Factors/immunology , Prosencephalon/cytology , Rats , Rats, Wistar , Taste/physiology , Thalamus/chemistry , Thalamus/cytology , Thalamus/physiologyABSTRACT
En ratas Wistar normales y tratadas neonatalmente con tiroxina, se obtuvieron cortes seriados del tálamo, teñidos con el método de Golgi-Cox en las edades de 12,20 y 30 días. En la zona de núcleo reticular talámico (TRN), se contó el número de neuronas visibles, el área y la máxima extensión transversal del TRN en un total de 120 secciones. Los hallazgos indicaron que con relación al numero de neuronas en los animales tratados con T4, ocurrió un incremento signifiativo inicial de ellas a los 12 días de edad, seguido de un decremento igualmente significativo a los 20 y 30 días postnatales. Con respecto al área y a la máxima extensión transversal del TRN, sólo se observó una reducción progresiva que alcanzó sus valores más bajos a los 30 días de edad, sin ocurrir el incremento inicial que se ha descrito para el tejido neuronal. Los hallazgos sugieren que el tratamiento neonatal con T4, pudiera interferir con el desarrollo neuronal del TRN y, asimismo, a largo plazo, con las funciones modulatorias sensoriales del TRN