Neurotensin-containing pathway from the endopiriform nucleus and the adjacent prepiriform cortex to the dorsomedial thalamic nucleus in the rat

Neural Representation of Odor-Guided Behavior in the Rat Olfactory Thalamus

The mediodorsal thalamus (MDT) is a higher-order corticocortical thalamic nucleus involved in cognition and memory. However, anatomically, the MDT is also the primary site of olfactory representation in the thalamus, receiving strong inputs from olfactory cortex and having reciprocal connections with orbitofrontal cortex (OFC). Nonetheless, its role in olfaction remains unclear. Here, we recorded single units in the MDT, as well as local field potentials in the MDT, piriform cortex (PCX), and OFC in rats performing a two-alternative odor discrimination task. We show that subsets of MDT units display odorant selectivity during sampling, as well as encoding of spatio-motor aspects of the task. Furthermore, the olfactory trans-thalamic network rapidly switches functional connectivity between MDT and cortical areas depending on current task demands, with, for example, MDT-PCX coupling enhanced during odor sampling and MDT-OFC coupling enhanced during the decision/goal approach compared with baseline and presampling. These results demonstrate MDT representation of diverse sensorimotor components of an olfactory task.

SIGNIFICANCE STATEMENT

The mediodorsal thalamus (MDT) is the major olfactory thalamic nucleus and links the olfactory archicortex with the prefrontal neocortex. The MDT is well known to be involved in higher-order cognitive and memory functions, but its role in olfaction is poorly understood. Here, using single-unit and local field potential analyses, we explored MDT function during an odor-guided decision task in rats. We describe MDT odor and multisensory coding and demonstrate behavior-dependent functional connectivity within the MDT/sensory cortex/prefrontal cortex network. Our results suggest a rich representation of olfactory and other information within MDT required to perform this odor-guided task. Our work opens a new model system for understanding MDT function and exploring the important role of MDT in cortical-cortical communication.

The olfactory thalamus: unanswered questions about the role of the mediodorsal thalamic nucleus in olfaction

The mediodorsal thalamic nucleus (MDT) is a higher order thalamic nucleus and its role in cognition is increasingly well established. Interestingly, components of the MDT also have a somewhat unique sensory function as they link primary olfactory cortex to orbitofrontal associative cortex. In fact, anatomical evidence firmly demonstrates that the MDT receives direct input from primary olfactory areas including the piriform cortex and has dense reciprocal connections with the orbitofrontal cortex. The functions of this olfactory pathway have been poorly explored but lesion, imaging, and electrophysiological studies suggest that these connections may be involved in olfactory processing including odor perception, discrimination, learning, and attention. However, many important questions regarding the MDT and olfaction remain unanswered. Our goal here is not only to briefly review the existing literature but also to highlight some of the remaining questions that need to be answered to better define the role(s) of the MDT in olfactory processing.

Neurotensin afferents of the ventral tegmental area in the rat: [1] re-examination of their origins and [2] responses to acute psychostimulant and antipsychotic drug administration

The ventral tegmental area (VTA) is involved in reward-related behaviours and the actions of psychostimulant drugs. It is influenced by afferents expressing a variety of neurotransmitters and neuromodulators; the innervation containing neurotensin is among the densest of these. Intra-VTA neurotensin activates dopaminergic neurons and plays an important role in the development of behavioural sensitization to psychostimulant drugs and possibly in schizophrenia. Using gold-coupled wheatgerm agglutinin as retrograde tracer in combination with nonisotopic in situ hybridization for neurotensin mRNA or neurotensin antibodies after colchicine treatment, the present study was undertaken to demonstrate the neurotensinergic neurons projecting to the VTA and determine whether (and in which subpopulations) neurotensin expression is regulated in VTA-projecting neurons after administrations of the psychostimulant drug methamphetamine or the antipsychotic haloperidol. This study reveals the lateral preoptico-rostral lateral hypothalamic continuum and the medial preoptic area as main sources for the neurotensin afferents of the VTA. Fewer neurotensinergic, VTA-projecting neurons are situated in the dorsal raphe, pedunculopontine and laterodorsal tegmental nuclei, lateral hypothalamic area, ventral endopiriform area, lateral septum, accumbens shell, parabrachial nucleus and different parts of the extended amygdala. The number of neurotensinergic VTA-projecting neurons increased significantly only after methamphetamine administration and exclusively in the accumbens shell. It is concluded that the widespread neurotensinergic VTA-projecting neurons, situated in areas involved in different reward-related behaviours, are well suited to convey distinct reward information to the VTA. The up-regulation of neurotensin expression selectively in VTA-projecting neurons in the accumbens shell following methamphetamine administration may be an important factor in the development of behavioural sensitization.

Sources of presumptive glutamatergic/aspartatergic afferents to the mediodorsal nucleus of the thalamus in the rat

The distribution of presumptive glutamatergic and/or aspartatergic neurons retrogradely labeled following injections of 3HD-aspartate into the mediodorsal nucleus of the thalamus (MD) in the rat was compared to the distribution of neurons labeled by comparable injections of the nonspecific retrograde tracer wheat germ agglutinin conjugated horseradish peroxidase (WGA-HRP). Cells retrogradely labeled by WGA-HRP were found in the prefrontal and agranular insular cortices; in forebrain structures such as the amygdaloid complex, the piriform cortex, the ventral pallidum and the reticular nucleus of the thalamus; and in several different parts of the brainstem, such as the superior colliculus, central grey, and substantia nigra, pars reticulata. Some, but not all, of these projections are presumably glutamatergic and/or aspartatergic. The projections to MD from the prefrontal and agranular insular cortices are well labeled with 3H-D-aspartate, as are projections from the anterior cortical amygdaloid nucleus. Projections from the superior colliculus to the lateral portion of MD also label with this tracer. However, other forebrain and brainstem projections to MD are not labeled with 3H-D-aspartate, and apparently do not use glutamate or aspartate as a neurotransmitter. These include the projections from the basal and accessory basal amygdaloid nuclei, as well as possibly GABAergic projections from the ventral pallidum and the substantia nigra, pars reticulata. A small fraction of the cells in the piriform cortex that project to MD label with 3H-D-aspartate, suggesting that this projection may be heterogeneous. In other experiments, presumptive GABAergic projections to MD were studied by using 3H-GABA as a retrograde tracer. Although in these cases the thalamic reticular nucleus is well labeled, the ventral pallidum and the substantia nigra, pars reticulata are only poorly labeled. Pallidal projections to the ventromedial thalamic nucleus (VM), which are likely to be GABAergic, were also studied with this technique. After injections of 3H-GABA into VM, only a few cells in the substantia nigra, pars reticulata, or entopeduncular nucleus were labeled. This result suggests 3H-GABA has limited usefulness as a transmitter-specific retrograde tracer.

Postnatal ontogeny of cells expressing prepro-neurotensin/neuromedin N mRNA in the rat forebrain and midbrain: a hybridization histochemical study involving isotope-labeled and enzyme-labeled probes

The postnatal ontogeny of cells expressing prepro-neurotensin/neuromedin N messenger RNA (prepro-NT/NN mRNA) in the rat forebrain and midbrain was investigated by in situ hybridization histochemistry. According to the pattern of expression during development, the cells which express prepro-NT/NN mRNA can be roughly divided into 2 groups. In type I cells, prepro-NT/NN mRNA expression reaches a maximum in terms of content during the postnatal period. After this early peak, cells of this type express the same or less prepro-NT/NN mRNA, reaching a plateau at an adult level that still contains a high level of expression. In type II cells, prepro-NT/NN mRNA appears during the postnatal period, and the expression decreases dramatically after the first postnatal week, being almost undetectable by a few weeks after birth. Type I cells were observed in the following areas: the piriform cortex, field CA1 of Ammon's horn, subiculum, vertical, and horizontal limbs of the diagonal band of Broca, intermediate part of the lateral septal nucleus, bed nucleus of the stria terminalis, medial preoptic area, lateral hypothalamus, caudal part of the caudate putamen, medial, cortical, and central amygdaloid nuclei, ventral tegmental area, deep mesencephalic nucleus, cuneiform nucleus, dorsal raphe nucleus, laterodorsal tegmental nucleus, parabrachial nucleus, and oral part of the pontine reticular nucleus. Cells of type II were observed in the following areas: the mitral cell layer of the olfactory bulb, rostral part of the caudate putamen, (anterior) cingulate cortex, and retrosplenial cortex (posterior cingulate cortex).

An ultrastructural study of neurotensin-like immunoreactive terminals in the mediodorsal thalamic nucleus of the rat

Neurotensin-like immunoreactive (NTir) axon terminals in the mediodorsal nucleus of the thalamus (MD) in the adult rat were demonstrated by electron microscopic immunohistochemistry. Most NTir terminals were large (greater than 2 microns in diameter) with round synaptic vesicles and asymmetrical synaptic contacts although smaller (less than 1.5 microns in diameter) axon terminals were also labeled. Both types of terminals were found in the medial and central parts of MD with the greatest density in the medial part. These NTir boutons have similar ultrastructural features as anterogradely labeled terminals from the piriform cortex and the preoptic area, which have previously been identified as sources of NTir axons in MD. A few NTir boutons were also found in the medial part of MD with pleomorphic vesicles and symmetrical synaptic contacts.

Neurotensin-like immunoreactivity in the diencephalon of the adult male cat

Using an indirect immunoperoxidase technique, the location of neurotensin-like fibers and cell bodies was studied in the diencephalon of the cat. The findings showed that the hypothalamus is richer in neurotensin-like-immunoreactive structures than the thalamus, and that neurotensin-like-immunoreactive structures are more widely distributed in the hypothalamus than in the thalamus. A high density of immunoreactive fibers was observed in the hypothalamic regions, area hypothalamica dorsalis, hypothalamus posterior, nucleus (n.) filiformis and n. arcuatus, whereas a moderate density was found in the n. parafascicularis, n. paraventricularis anterior, hypothalamus lateralis, median eminence and n. paraventricularis hypothalami. Other diencephalic regions such as n. lateralis posterior, n. lateralis dorsalis, n. medialis dorsalis, n. habenularis lateralis, n. centrum medianum, n. rhomboidens, n. reuniens, hypothalamus anterior, n. supra chiasmaticus, hypothalamus ventromedialis, n. supraopticus and hypothalamus dorsomedialis had the lowest density of immunoreactive fibers. In addition, the densest clusters of neurotensin-like perikarya were found in the n. arcuatus, n. centralis medialis and hypothalamus posterior, whereas the n. medialis dorsalis, n. paraventricularis anterior, n. reuniens, hypothalamus lateralis and hypothalamus ventromedialis had the lowest density. In the n. lateralis dorsalis, n. supraopticus, area hypothalamica dorsalis and n. supra chiasmaticus the density of immunoreactive perikarya was moderate.

Postnatal changes in the density and distribution of neurotensin-like immunoreactive fibers in the mediodorsal nucleus of the thalamus in the rat

A previous report (Inagaki et al., Brain Res. 260:143-146, '83) suggested that the peptide neurotensin is contained in neurons of the piriform cortex that project to the mediodorsal thalamic nucleus (MD) in young rats. To confirm this, we have studied the distribution of neurotensin-like immunoreactive (NTIR) fibers in MD during development, using three antisera directed at different parts of the neurotensin molecule (Emson et al., J. Neurochem. 38:992-999, '82). In adult rats, NTIR fibers in MD are sparse. They are located mostly at the medial edge of MD and in the adjacent midline thalamic nuclei, with a few poorly stained NTIR fibers in the central part of MD. In contrast, during the first postnatal week, both the medial and central portions of MD stain heavily for neurotensin. The density of NTIR fibers in MD then progressively decreases until the density typical of adult rats is reached, at about 5 weeks. Changes in the distribution of NTIR fibers in MD also occur. In 7-day-old rats, the patches of NTIR fibers in the medial and central parts of MD are contiguous, but by 10 days a sparsely immunoreactive zone forms between them. With maturation, this zone enlarges as the density of neurotensin staining decreases, until the medial contingent of NTIR fibers reaches its adult position at the medial edge of MD. From a comparison of the distribution of NTIR cells with that of cells that can be retrogradely labeled from MD or the midline thalamus, the probable source of the NTIR fibers to the central part of MD is in the deep layer of the piriform cortex, while the NTIR fibers to the medial edge of MD and the midline nuclei may arise from the preoptic region and the medial amygdala. In neonatal rats, neurons are found in the piriform cortex, the preoptic region, and the medial amygdala, which can be double-labeled both for neurotensin and with a retrograde tracer injected into MD and the midline thalamus. Projections of the preoptic region to the thalamus have a distribution similar to that of the medial population of NTIR fibers, whereas the distribution of piriform cortical afferents in central MD matches the central patch of NTIR fibers.

Distribution of tachykinin- and enkephalin-immunoreactive fibers in the human thalamus

Sections at regular intervals through the human thalamus and alternating with those used for histochemical and cytoarchitectonic analysis in the companion paper, were stained immunocytochemically with a monoclonal antibody that recognizes tachykinins, including substance P, and with an antiserum against metenkephalin-arg-gly-leu (MERGL). Immunoreactivity for both types of molecule is found in fiber systems that enter the thalamus: (a) anteromedially, from the hypothalamus and prethalamic regions; (b) posterolaterally, from the midbrain tegmentum. No immunoreactive somata were observed in the thalamus. The chief nuclei in which dense, apparently terminal, ramifications of both sets of immunoreactive fibers are found include the posterior complex (Po, L and Sg), the intralaminar nuclei except the centre median, and a small nucleus tentatively identified as the nucleus submedius. It is significant that many of these nuclei have been implicated in pain phenomena, that most of them receive spinothalamic inputs, and that spinal cells at the origins of the tract are immunoreactive for substance P or metenkephalin. This study provides further evidence for the close similarity between nuclear delineation in the human and monkey thalami.

Current generators and properties of late components evoked in rat olfactory cortex

Following main olfactory bulb (MOB) stimulation at frequencies of 0.1-0.3 Hz, in addition to early field potentials, a frequency-sensitive, surface negative late N2 wave (latency range: 63-96 msec) followed occasionally by a late N3 transient, was evoked in the piriform cortex and endopiriform nucleus of the rat. The N2 wave inverted polarity at the Ib-II cortical layer interface (P2 wave) and was associated with late unit discharges 200 to 1200 microns deep to the turnover point. Response probability, peak latency, recovery curve and frequency-sensitivity of the P2 wave were not significantly different in animals under urethane or pentobarbital. Current-source-density (CSD) analysis revealed that the N2 wave generators were localized to the Ib-II layer interface. Since inhibitory activity does not contribute substantially to the second derivative curve, CSD analysis strengthens the assumption that late components (LCs) are excitatory events (compound EPSPs) presumably generated on the proximal apical dendritic segments of pyramidal cells by association axons. The early "b" wave in a test response was facilitated, rather than occluded, when a LC was present in the conditioning response, or when the priming volley was delivered to the mediodorsal thalamic nucleus. Clustering of unit and field activity in two distinct periods of the evoked response separated by a prolonged interval of cell silence suggests that cortical coding of olfactory cues might be more efficiently achieved by temporal modulation of the neuronal response rather than by spatial distribution of firing patterns.

Afferent projections to the dorsal thalamus of the rat as shown by retrograde lectin transport--I. The mediodorsal nucleus

The topography of afferent projections to the mediodorsal thalamic nucleus of the rat has been studied using the retrograde transport of unconjugated wheat germ agglutinin as identified by immunocytochemistry. Inputs were defined according to the lateral, central or medial segments of the nucleus injected, and controlled by additional injections into the habenula, central medial and paraventricular nuclei of the thalamus. Cortical afferents to the lateral segment arose from anterior cingulate and prelimbic areas on the medial surface of the hemisphere, those to the central segment arose mainly from ventral orbital area, whilst those to the medial segment arose from the infra-limbic and agranular insular areas. This strict cortical topography was matched by the organization of afferents from the reticular thalamic nucleus; i.e. lateral, intermediate and medial reticular neurons from the rostral nucleus projected to lateral, central and medial segments of the mediodorsal thalamus respectively. In the basal forebrain ventral pallidum projected only to the medial segment, whilst magnocellular preoptic region projected only to the central segment. Lateral preoptic area projected to lateral and central segments and the diagonal band mainly to central segment. Projections from substantia innominata were found regardless of the area of mediodorsal nucleus injected. The paraventricular nucleus of thalamus, lateral habenula and substantia nigra reticulata projected to the lateral segment only, whilst central gray projected only to the medial segment. Projections from amygdala (mainly basolateral and central nucleus) were found only following central and medial segment injections. All regions of the mediodorsal nucleus injected received input from the lateral hypothalamus, the ventral tegmental area and the dorsal tegmental gray. The results are discussed and particular emphasis is placed on the possible functions of the thalamocortical connections and the role of the reticular thalamic nucleus as a potential regulator of thalamocortical activity.

Cholecystokinin innervation of rat thalamus, including fibers to ventroposterolateral nucleus from dorsal column nuclei

The distribution of cholecystokinin octapeptide immunoreactive fibers and puncta in the adult rat thalamus was studied using immunocytochemical methods. Small to moderate numbers of immunoreactive fibers were present in the lateral habenular nucleus, ventral lateral geniculate nucleus, zona incerta, parataenial, mediodorsal, medioventral, and submedial nuclei, the rhomboid, paracentral, central lateral and parafascicular nuclei, and in the medial geniculate and dorsal lateral geniculate nuclei. Moderate to large numbers of cholecystokinin (CCK)-positive fibers were present in the paraventricular nuclei, the reticular nucleus, the anteroventral, anteromedial, and central medial nuclei, and in the rostral extension of the internal medullary lamina between the parataenial and anteroventral nuclei. Dense concentrations of immunoreactive fibers were also found in a principal sensory relay nucleus, the ventroposterolateral nucleus (VPL), of the ventrobasal complex. The number of CCK-positive fibers in VPL showed a marked unilateral decrease in rats which had received lesions of the contralateral gracile and cuneate nuclei. The results of this study demonstrate that CCK-immunoreactive fibers and puncta are widely distributed in the rat thalamus, and that the source of these fibers in VPL is probably the dorsal column nuclei.

Distributions of certain neuropeptides in the primate thalamus

The distributions of fibers and terminals immunoreactive for somatostatin (SRIF), neuropeptide Y (NPY), substance P (SP) and cholecystokinin octapeptide (CCK), were studied in the diencephalon of cynomolgus monkeys. Immunoreactivity for all 4 peptides is found in extrinsic afferent fibers innervating the dorsal thalamus, ventral thalamus and epithalamus. The distributions of such fibers are more extensive than previously described and include many relay nuclei in their zones of terminations. SP fibers are particularly concentrated in the ventral posteromedial nucleus. All peptides are especially concentrated in fibers in the intralaminar and reticular nuclei. Afferent fibers immunoreactive for each of the 4 peptides approach the thalamus by two pathways. An anterior route is formed by the classical periventricular system ascending from the hypothalamus to the epithalamus. A posterior pathway ascends in the lateral midbrain tegmentum and provides innervation to posterior, intralaminar, and many relay nuclei, plus the ventral thalamus. A basal forebrain pathway, containing SRIF and NPY immunoreactive fibers, enters the thalamus in association with the ansa lenticularis and SP fibers also ascend from the substantia nigra.

Neurotensin immunoreactive neurons in the human infant diencephalon

Neurotensin-like immunoreactive (NT-IR) neurons are present in discrete subregions of the anterior, medial and lateral thalamic nuclear groups of the human infant brain. The pulvinar is notably rich in such cells. Smaller numbers of cells are present in the ventral group, centromedian nucleus, reticular nuclei and intralaminar nuclei. Neurotensin immunoreactive axons accumulate dorsally in the thalamus and cross the deep white matter. The cerebral cortex contains a rich network of NT-IR axons. The subthalamic nucleus is rich in NT-IR neurons. Within the hypothalamus NT-IR perikarya are present in parts of the lateral and tuberal regions and in the lateral mammillary area. NT-IR axons are widespread being particularly prominent in parts of the tuberal region and the mammillary body.

The ventral striatopallidothalamic projection: II. The ventral pallidothalamic link

The projection of ventral pallidal neurons to the mediodorsal nucleus of the thalamus (MD) was examined in rats by combined retrograde transport of horseradish peroxidase (HRP) after injections in the MD and glutamate decarboxylase (GAD) immunocytochemistry at light and electron microscopic levels, with and without prior exposure of the brains to colchicine. HRP was transported to the soma of medium-sized and large ventral pallidum neurons, which along with their long, large dendrites were contacted by many glutamate decarboxylase immunoreactive synaptic boutons. The retrograde tracer positive neurons bore a remarkable resemblance to the projecting cells of the globus pallidus and entopeduncular nucleus. When colchine exposure was included in the tissue preparation, some but not all tracer positive cells also exhibited cytoplasmic GAD immunoreactivity.

Current generators and properties of early components evoked in rat olfactory cortex

Depth-profile, current-source-density (CSD) and impedance analysis were used to determine the current generators of secondary waves "a" and "b" in the response evoked in pyriform cortex (PC) of the urethane anesthetized rat following OB or LOT stimulation. Positive peaks (sinks) in the second-derivative curves of the "a" and "b" waves were localized at 50-75 and 225-250 microns deep, respectively. Cortical impedance was significantly (p less than 0.01) correlated with the cell packing density of PC layers, being maximal close to the zero dipole point of the gross evoked response; magnitude of conductivity gradients was, however, insufficient to alter the interpretation of positive and negative peaks in terms of net membrane currents. Post-tetanic and/or frequency potentiation of PC responses but not long-term potentiation were found in the majority of animals tested. Recovery of the test "b" wave was faster when using paired-shock stimulation at 3.0 Hz than at 0.3 Hz; suppression of this component following a conditioning OB volley could be overcome and the "b" wave facilitated if either a long-latency component (i.e., 65-100 msec) was present in the priming response, or if the conditioning stimulus was delivered to the mediodorsal thalamic nucleus (MDT). These results confirm and extend similar ones in other species, suggesting that following OB or LOT stimulation three successive excitatory processes take place in PC neural elements of the rat under urethane anesthesia: an initial monosynaptic excitation of distal segments of apical dendrites of layer II cells, and to a lesser extent, also of layer III neurons ("a" wave), followed by action potentials in their respective somas (PS wave); subsequently, long association axons give rise to a di or polysynaptic compound EPSP in proximal apical and possibly also, in basal pyramidal dendrites ("b" wave; early reactivation process). Finally, a "late" reactivation takes place in PC involving neurons which participated in the early reactivation process (late component). In addition, heterosynaptic facilitation of the "b" wave in the PC evoked response follows MDT conditioning stimulation.

Distribution and origins of neurotensin-containing fibers in the nucleus ventromedialis hypothalami of the rat: an experimental immunohistochemical study

The distribution and origins of neurotensin (NT)-containing fibers in the nucleus ventromedialis hypothalami (VM) of the rat were investigated experimentally using an indirect immunofluorescence technique. A dense plexus of NT-like immunoreactive (NTI) fibers which was composed of very fine varicosities was identified in the VM. Although they were distributed throughout its entire rostrocaudal extent, the distribution was uneven. The highest density was identified in the dorsomedial part of the VM. In the central part, a less numerous but still moderate number of NTI fibers was detected in its dorsal part. But in a ventrolateral direction, they decreased in number and in the ventrolateral part only a few NTI fibers were seen. The present study demonstrated experimentally that these fibers originate from the medial nucleus of the amygdaloid complex (AM), since destruction of the AM resulted in a marked reduction of NTI fibers ipsilaterally in the VM. These findings suggest that the AM influences the VM's functions via neurotensin-like immunoreactive fibers.