Eric E.O. Colago

Corticotropin-releasing factor-containing axon terminals synapse onto catecholamine dendrites and may presynaptically modulate other afferents in the rostral pole of the nucleus locus coeruleus in the rat brain.

Physiological and immunohistochemical studies have suggested that corticotropin‐releasing factor (CRF), the hypophysiotropic peptide that initiates endocrine responses to stress, may serve as a neurotransmitter to activate noradrenergic neurons in the nucleus locus coeruleus (LC). We combined immunoperoxidase labeling for CRF and immunogold‐silver localization of the catecholamine‐synthesizing enzyme tyrosine hydroxylase (TH) in single sections through the rat LC to determine potential substrates for interactions between these two transmitters. Light microscopic analysis indicated that CRF processes are dense and highly varicose in the rostral LC region in the vicinity of noradrenergic dendrites. Electron microscopy of this rostral region revealed that immunoperoxidase labeling for CRF was mainly restricted to axons and axon terminals and was rarely seen in somata or dendrites. Axon terminals containing CRF immunoreactivity varied in size, content of synaptic vesicles, and formation of synaptic specializations. The postsynaptic targets of the CRF‐labeled axon terminals consisted of both TH‐labeled dendrites and dendrites lacking detectable TH‐immunoreactivity. Of 113 CRF‐immunoreactive axon terminals, approximately 70% were in direct contact with TH‐labeled and unlabeled dendrites. Of the CRF‐labeled axon terminals forming synapses with TH‐labeled and unlabeled dendrites, they were either of the asymmetric (excitatory type; 19%) or symmetric (inhibitory type; 11%) variety or did not form identifiable contacts in the plane of section analyzed. Unlabeled axon terminals and glial processes were also commonly located adjacent to the plasma membranes of CRF‐labeled axon terminals.

Dopamine D1 receptors co-distribute with N-methyl-d-aspartic acid type-1 subunits and modulate synaptically-evoked N-methyl-d-aspartic acid currents in rat basolateral amygdala

Activation of dopamine D1 or glutamate, N-methyl-d-aspartic acid (NMDA) receptors in the basolateral amygdala (BLA) can potently influence affective behaviors and associative learning. Physical protein-protein interactions also can occur between C-terminal peptides of D1 receptors and the NMDA-receptor subunit-1 (NR1), suggesting intracellular associations of direct relevance to dopaminergic modulation of NMDA currents. We examined this possibility by combining electron microscopic immunolabeling of the D1 and NR1 C-terminal peptides with in vitro patch-clamp recording in the rat BLA. In the in vivo preparations, D1 and NR1 were localized to the surface or endomembranes of many of the same somata and dendrites as well as a few axon terminals, including those forming asymmetric, excitatory-type synapses. In vitro analysis of physiologically characterized projection neurons revealed an excitatory response to bath application of either dopamine or the preferential D1 receptor agonist, dihydrexidine. In these neurons, dopamine also selectively reduced stimulation-evoked isolated NMDA receptor-mediated currents, but not isolated non-NMDA receptor-mediated currents or the response to exogenous NMDA application. The selective reduction of the NMDA receptor-mediated currents suggests that this effect occurs at a postsynaptic locus. Moreover, both D1 and NR1 were localized to postsynaptic surfaces of biocytin-filled and physiologically characterized projection neurons. Our results provide ultrastructural evidence for D1/NR1 endomembrane associations that may dynamically contribute to the attenuation of NMDA receptor-mediated currents following prior activation of D1 receptors in BLA projection neurons. The potential for postsynaptic cross-talk between D1 and NMDA receptors in BLA projection neurons as well as a similar interaction in presynaptic terminals could have important implications for the formation and extinction of affective memories.

Contingent and non-contingent effects of heroin on mu-opioid receptor-containing ventral tegmental area GABA neurons

Opiate activation of mu-opioid receptors (muORs) in the ventral tegmental area (VTA) modulates gamma-aminobutyric acid (GABA) neurotransmission within the mesocorticolimbic dopamine (DA) reward system. We combined in vivo extracellular electrophysiological recordings in anesthetized and freely behaving rats with intracellular Neurobiotin filling and immunocytochemistry to characterize the effects of opiates on VTA GABA neurons, evaluate their discharge activity during opiate self-administration, and identify the cellular sites for opiate activation. We identified a subpopulation of VTA GABA neurons that was characterized by location, spike discharge profile, activation by microelectrophoretic DA, and response to internal capsule (IC) stimulation. Systemic administration of heroin or microelectrophoretic application of the selective muOR agonist [d-Ala2, N-Me-Phe4, Gly-ol]-Enkephalin (DAMGO) reduced VTA GABA neuron firing rate (heroin IC(50) = 0.35 mg/kg) and was blocked by the muOR antagonist naloxone. Heroin also reduced IC-evoked post-stimulus spike discharges, a manifestation of gap-junction-mediated electrical coupling between VTA GABA neurons. The baseline firing rate of VTA GABA neurons significantly increased (239%) following the acquisition of heroin self-administration behavior and transiently increased during each response for heroin (105%), but decreased (49%) following heroin, similar to non-contingent heroin. Electrophysiologically characterized VTA GABA neurons were filled with Neurobiotin and labeled dendrites contained plasmalemmal muOR immunoreactivity. Dually labeled muOR dendrites contained dendrodendritic appositions characteristic of gap junctions. These findings indicate that inhibition of this population of GABAergic neurons by opiates acting on dendritic muORs has implications for modulation of electrical coupling between VTA GABA neurons and dopamine (DA) neurotransmission in the VTA and terminal field regions.

Selective distribution of the NMDA‐R1 glutamate receptor in astrocytes and presynaptic axon terminals in the nucleus locus coeruleus of the rat brain: An immunoelectron microscopic study

The regional and cellular distribution of the different classes of excitatory amino acid receptors with respect to the noradrenergic neurons of the nucleus locus coeruleus (LC) are unknown. We therefore combined immunoperoxidase labeling for the R1 subunit of the N‐methyl‐D‐aspartate (NMDA) receptor with immunogold‐silver localization of the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH), in single sections through the rat LC to determine the subcellular localization of this glutamate receptor subtype with respect to the noradrenergic neurons. At the light microscopic level, there was light to moderate labeling for the NMDA‐R1‐like (li) receptor in the caudal pole of the LC and dense labeling in the dorsolateral aspect of the LC adjacent to the superior cerebellar peduncle. In the rostral pole of the LC which is enriched with noradrenergic dendrites, significant overlap between both immunoreactivities could be observed. At the ultrastructural level, immunoperoxidase labeling for NMDA‐R1 was selectively distributed in astrocytic processes and within presynaptic axon terminals but was rarely seen in catecholamine‐containing somata or dendrites. Peroxidase labeling for NMDA‐R1, however, was occasionally observed in dendrites in the rostral pole of the LC. Most of these dendrites lacked detectable levels of TH, although TH immunoreactivity was apparent in the neuropil. Dendrites containing NMDA‐R1‐li immunoreactivity often received asymmetric (excitatory‐type) contacts from unlabeled terminals. NMDA‐R1‐li‐immunoreactive axon terminals usually contained small clear, as well as large dense‐core vesicles and were often apposed to unlabeled dendrites, axon terminals and/or glial processes. These results provide the first ultrastructural evidence that NMDA‐R1‐li immunoreactivity is selectively distributed within astrocytic processes and presynaptic axon terminals within the LC.

Region-Specific Changes in the Subcellular Distribution of AMPA Receptor GluR1 Subunit in the Rat Ventral Tegmental Area after Acute or Chronic Morphine Administration

Opiate addiction is characterized by progressive increases in drug intake over time suggesting maladaptive changes in motivational and reward systems. These behaviors are mediated by dopaminergic neurons originating from the ventral tegmental area (VTA), and long-term changes of these dopaminergic neurons are attributed to increased postsynaptic glutamatergic activation. Indeed, chronic morphine administration is known to increase AMPA receptor glutamate receptor 1 (GluR1) subunit in the VTA. However, there is no ultrastructural evidence that morphine affects the expression or surface availability of GluR1 subunits in VTA neurons of defined distribution or transmitter phenotype. Therefore, we examined electron microscopic immunolabeling of GluR1 and tyrosine hydroxylase (TH) in two VTA regions of rats perfused 1 h after a single injection of morphine, or chronic morphine in intermittent-escalating doses for 14 d, and appropriate saline controls. Acute morphine administration produced a significant increase in GluR1 immunogold particles at the plasma membrane and postsynaptic densities in both TH- and non-TH-containing dendrites in the parabrachial VTA, a region that contains mainly prefrontal-cortical-projecting dopaminergic neurons involved in motivation and drug-seeking behavior. Chronic morphine administration maintained the increased synaptic GluR1 labeling in the parabrachial VTA, but also increased the number of GluR1-labeled synapses and TH immunoreactivity in dendrites of the paranigral VTA where substantially more dopaminergic neurons project to limbic structures implicated in locomotor activation and reward. These results demonstrate a region- and dose-dependent redistribution of GluR1-containing AMPA receptors, which is consistent with acute morphine activation of cortical-projecting VTA neurons and chronic morphine activation of limbic-projecting VTA neurons.

Light and electron microscopic evidence for topographic and monosynaptic projections from neurons in the ventral medulla to noradrenergic dendrites in the rat locus coeruleus

Physiological studies have shown that afferents from the nucleus paragigantocellularis (PGi) in the rostral ventral medulla underlie the modulation of locus coeruleus (LC) activity by a variety of stimuli. However, there have been no anatomical demonstrations of a monosynaptic projection from neurons in the PGi to the LC. Thus, biotinylated dextran amine (BDA) was iontophoretically injected into the ventral medulla and single-tissue sections were processed for peroxidase localization of BDA and gold-silver labeling of tyrosine hydroxylase (TH). Discrete microinjections of BDA were placed into either the medial or lateral aspects of the ventral medulla. For medially placed injections, a medio-dorsal pathway to the LC was observed. This trajectory resulted in a predominant innervation of the ventral LC. Lateral injection placements yielded a fiber pathway that coursed more laterally within the medullo-pontine reticular formation and primarily innervated the dorsolateral LC. These light microscopic data suggested that neurons in the PGi use distinct pathways to innervate the LC and are topographically organized within this structure. Electron microscopic analyses of the LC region indicated that axon terminals originating from either subregion were equally likely to contact noradrenergic neurons in the LC. Approximately 57% and 62% of BDA-labeled terminals originating from the medial (n=150) or lateral (n=150) aspects of the ventral medulla, respectively, formed heterogeneous synaptic contacts (i.e., inhibitory- and excitatory-type) with dendrites containing TH. It is well known that the PGi is a functionally diverse region that is involved in sensory integration, autonomic regulation and pain modulation. It is also known that LC efferents are spatially organized with respect to their postsynaptic targets. Taken together, our findings that subdivisions of the ventral medulla topographically and monosynaptically innervate the LC suggest that regionally specific PGi neurons target subsets of LC neurons with efferent targets that may possess analogous functional correlates.

Mu‐opioid receptor is located on the plasma membrane of dendrites that receive asymmetric synapses from axon terminals containing leucine‐enkephalin in the rat nucleus locus coeruleus

We have recently shown, by using immunoelectron microscopy, that the mu‐opioid receptor (μOR) is prominently distributed within noradrenergic perikarya and dendrites of the nucleus locus coeruleus (LC), many of which receive excitatory‐type (i.e., asymmetric) synaptic contacts from unlabeled axon terminals. To characterize further the neurotransmitter present in these afferent terminals, we examined in the present study the ultrastructural localization of an antipeptide sequence unique to the μOR in sections that were also dually labeled for the opioid peptide leucine‐enkephalin (L‐ENK). Immunogold‐silver labeling for μOR was localized to extrasynaptic portions of the plasma membranes of perikarya and dendrites. The μOR‐labeled dendrites were usually postsynaptic to axon terminals containing heterogeneous types of synaptic vesicles and forming asymmetric synaptic specializations characteristic of excitatory‐type synapses. The majority of these were immunolabeled for the endogenous opioid peptide L‐ENK. Some μOR‐labeled dendrites received synaptic contacts from unlabeled axon terminals in fields containing L‐ENK immunoreactivity. In such cases, the μOR‐labeled dendrites were in proximity to L‐ENK axon terminals that contained intense peroxidase labeling within large dense core vesicles along the perimeter of the axoplasm. These results indicate that L‐ENK may be released by exocytosis from the dense core vesicles and diffuse within the extracellular space to reach μOR sites on the postsynaptic dendrite or dendrites of other neighboring neurons. The present study also reveals that unlabeled terminals apposed to μOR‐labeled dendrites may contain other opioid peptides, such as methionine‐enkephalin. These data demonstrate several sites where endogenous opioid peptides may interact with μOR receptive sites in the LC and may provide an anatomical substrate for the LCs involvement in mechanisms of opiate dependence and withdrawal.

κ-Opioid and NMDA glutamate receptors are differentially targeted within rat medial prefrontal cortex

Activation of κ-opioid receptors (KOR) in the medial prefrontal cortex (mPFC) modulates excitatory transmission, which may involve interactions with N-methyl-d-aspartate (NMDA) glutamate receptors. We investigated possible anatomical correlates of this modulation by using dual labeling electron microscopy to examine the cellular distributions of antibodies raised against KOR and the R1 subunit of the NMDA receptor (NR1). KOR immunoreactivity primarily was localized to plasma and vesicular membranes of axons and axon terminals that were morphologically heterogeneous. A small proportion of KOR immunoreactivity was associated with cytosolic compartments of dendrites and membranes of glial processes. NR1 labeling was mainly postsynaptic, associated most often with membranes of cytoplasmic organelles in cell bodies and large dendrites and plasmalemmal surfaces of distal dendrites. The remaining NR1-labeled profiles were axonal profiles and glial processes. Of all cellular associations between labeled profiles, the majority were KOR-labeled axons that contacted NR1-immunoreactive dendrites or cell bodies. Occasionally the two antigens were colocalized in axon terminals that formed either asymmetric synapses or displayed varicose morphology. KOR and NR1 also were colocalized within dendrites, and rarely were observed in the same cell bodies. Occasionally glial processes coursing adjacent to axo-spinous appositions expressed both KOR and NR1 immunoreactivity. These results indicate that ligand activation of KOR or NMDA receptors differentially modulates excitatory transmission in the mPFC through pre- and postsynaptic mechanisms, respectively. The data also suggest more minor roles for colocalized KOR and NMDA receptors in shared regulation of presynaptic transmitter release, postsynaptic responsivity, and glial function.

Chronic administration of morphine is associated with a decrease in surface AMPA GluR1 receptor subunit in dopamine D1 receptor expressing neurons in the shell and non-D1 receptor expressing neurons in the core of the rat nucleus accumbens

The nucleus accumbens (Acb) is an extensively studied neuroanatomical substrate of opiate reward and the neural plasticity associated with chronic opioid use. The cellular mechanisms mediating opioid-dependent plasticity are uncertain, however AMPA-type glutamate receptor trafficking in dopamine D1 dopamine receptor (D1R) expressing neurons may be a potential cellular pathway for these adaptations, although there is no evidence for this possibility. Immunogold electron microscopy was used to quantify the surface expression of the AMPA GluR1 subunit in dendritic profiles of neurons in the Acb in response to intermittent 14-day non-contingent injections of escalating doses of morphine, a model that parallels opioid self-administration. To determine if changes in GluR1 trafficking occurred in neurons potentially sensitive to dopamine-induced D1R activation, immunoperoxidase labeling of D1R was combined with immunogold labeling of GluR1. Immunogold quantification was performed in two distinct Acb subregions, the shell, an area involved in processing incentive salience related to rewarding stimuli, and the core, an area involved in reward-seeking behaviors. We provide the first report that chronic morphine administration is associated with a receptor-phenotypic decrease in surface trafficking of GluR1 in Acb subregions. When compared to saline injected animals, morphine produced a decrease in plasma membrane GluR1 labeling in medium- and large-sized D1R expressing dendritic profiles in the Acb shell. In contrast, in the Acb core, surface GluR1 was decreased in small-sized dendrites that did not express the dopamine receptor. These results indicate that chronic intermittent injection of escalating doses of morphine is accompanied by ultrastructural plasticity of GluR1 in neurons that are responsive to glutamate and dopamine-induced D1R activation in the Acb shell, and neurons capable of responding to glutamate but not D1R receptor stimulation in the Acb core. Thus, AMPA receptor trafficking associated with chronic opiate exposure in functionally distinct areas of the Acb may be distinguished by D1R receptor activation, suggesting the potential for differing neural substrates of reward and motor aspects of addictive processes involving glutamate and dopamine signaling.

Enkephalin terminals form inhibitory-type synapses on neurons in the rat nucleus locus coeruleus that project to the medial prefrontal cortex

Norepinephrine-containing fibres in the medial prefrontal cortex derive from the locus coeruleus, a brainstem nucleus which also receives a dense innervation of enkephalin-immunoreactive axon terminals. We combined immunogold-silver labelling of retrogradely transported FluoroGold from the medial prefrontal cortex with immunoperoxidase detection of leucine5-enkephalin in the same section of tissue through the locus coeruleus of adult rats. This dual-labelling experiment was conducted to determine whether axon terminals containing lecuine5-enkephalin target neurons in the locus coeruleus that project to the frontal cortex and, if so, what are their morphological characteristics. By light microscopy, enkephalin-labelled processes overlapped FluoroGold retrogradely labelled neurons in the locus coeruleus. By electron microscopy, retrogradely labelled perikarya and dendrites were commonly enveloped by astrocytic processes and received few afferents in the plane of section examined. However, at sites unoccupied by glial processes, abundant afferent input could be identified. In addition, some FluoroGold-labelled perikarya and dendrites lacked this glial ensheathment but were more frequently apposed by axon terminals. Of 163 FluoroGold-labelled perikarya and dendrites examined where enkephalin immunoreactivity was present in the neuropil, 42% were contacted by enkephalin-immunoreactive axon terminals. The peroxidase-labelled enkephalin terminals as well as the unlabelled terminals often contained both small, clear and large dense core vesicles. Both labelled and unlabelled terminals also formed primary symmetric synapses characteristic of inhibitory transmitters with retrogradely labelled perikarya and proximal dendrites. At times, more than one enkephalin-labelled terminal was found to converge on a common retrogradely labelled perikarya or dendrite. These results demonstrate cellular sites where enkephalin-containing afferents may directly modulate and most likely inhibit the activity of cortically projecting neurons in the locus coeruleus.