Activation of RMTg projections to the VTA reverse cocaine-induced molecular adaptation in the reward system.

The rostromedial tegmental nucleus (RMTg) plays a crucial role in regulating reward-related behavior by exerting inhibitory control over the ventral tegmental area (VTA). This modulation of dopamine neuron activity within the VTA is essential for maintaining homeostasis in the reward system. Recently we have shown that activation of RMTg projections to the VTA during the acquisition of cocaine-conditioned place preference (CPP) reduces the rewarding properties of cocaine and decreases VTA dopamine neuron activity. By inhibiting dopamine neurons in the VTA, we hypothesized that RMTg projections hold the potential to restore reward system homeostasis disrupted by repeated cocaine use, and attenuate molecular adaptations in the reward system, including alterations in signaling pathways. Our study demonstrates that enhancing the GABAergic inputs from the RMTg to the VTA can mitigate cocaine-induced molecular changes in key regions, namely the VTA, nucleus accumbens (NAc), and prefrontal cortex (PFC). Specifically, we found that cocaine-induced alteration in the phosphorylation state of ERK (pERK) and GluA1 on serine 845 (S845) and serine 831 (S831), that play a major role in plasticity by controlling the activity and trafficking of AMPA receptors, were significantly reversed following optic stimulation of RMTg afferents to the VTA. These findings highlight the therapeutic potential of targeting the RMTg-VTA circuitry for mitigating cocaine reward. Ultimately, this research may pave the way for novel therapeutic interventions that restore balance in the reward system and alleviate the detrimental effects of cocaine.

Inactivation of PKMζ in the NAc shell abolished cocaine-conditioned reward.

Preventing relapse to drug use is a major challenge for the treatment of drug addiction. Environmental cues are among the major determinants of relapse in abstinent cocaine users. The protein kinase M ζ (PKMζ) is involved in the generation and maintenance of long-term potentiation and is critical in memory storage. Here we show that inhibition of PKMζ in the nucleus accumbens (NAc) shell, a major component of the reward system that plays an important role in mediating drug craving and relapse, by a selective inhibitor ζ inhibitory peptide (ZIP), abolished cocaine-induced conditioned place preference (CPP). However, the injection of ZIP into the NAc core resulted in earlier onset of CPP extinction. Finally, we found that the levels of PKMζ and GluR2 in the NAc remained unchanged, while the GluR1 levels were elevated following CPP and fully reversed by ZIP injection. Together, our results suggest that inactivation of PKMζ in the NAc may result in the dissociation between the rewarding properties of the drug and the drug-related environment and may serve as a novel target for the treatment of drug relapse.

Dopamine inhibits GABA(A) currents in ventral tegmental area dopamine neurons via activation of presynaptic G-protein coupled inwardly-rectifying potassium channels.

Dopamine (DA) neurons in the ventral tegmental area (VTA) constitute the origin of major dopaminergic neural pathways associated with essential functions including reward, motivation and cognition. Hence, regulation of VTA DA neurons' excitability is of important significance. Like other neurons, the activity level of VTA DA neurons is considerably determined by excitatory and inhibitory synaptic inputs. Here we show that DA itself, the most available modulator in the VTA, causes an inhibition of GABA receptor type A (GABA(A)R)-mediated evoked-IPSC (eIPSC) recorded from rat VTA DA neurons. The DA-induced inhibition was accomplished by activation of DA receptors, known to inhibit adenylyl cyclase activity (D2-like receptors), and was absent when these receptors were blocked. Moreover, blocking of either GABA receptor type B (GABA(B)R) or G-protein coupled inwardly-rectifying potassium (GIRK) channels was also found to effectively prevent the DA-induced inhibition of GABA(A)R eIPSC. In addition, we found that DA changes the values of both paired-pulse ratio (PPR) and coefficient of variation (CV) of GABA(A)R eIPSC amplitude, similar to the changes obtained by lowering the extracellular calcium concentration. Taken together, we propose that activation of D2-like receptors and GABA(B)R in the VTA enhances presynaptic GIRK channels activity, which in turn leads to reduced GABA release. The consequence of reduced GABA release on VTA DA neurons may contribute to their increased activity. Accordingly, a novel potential regulatory form of VTA DA neurons' excitability, which involves presynaptic potassium channels, is proposed.

Tempol diminishes cocaine-induced oxidative damage and attenuates the development and expression of behavioral sensitization.

A variety of mechanisms has been suggested for cocaine toxicity, including the possibility that cocaine induces an increase in oxidative stress (OS) due to excessive oxidation of dopamine (e.g. dopamine quinine), or by redox cycling of cocaine oxidized metabolites. However, the association between oxidative status in the brain and cocaine induced-behavior is poorly understood. Therefore, we examined the ability of the unique antioxidant tempol to attenuate cocaine-induced oxidative damage and behavioral response. Acute cocaine treatment significantly elevated OS markers in prefrontal cortex (PFC) and nucleus accumbens (NAc) in rats, both in slices and following a single cocaine injection, which corresponded with a decrease in total antioxidant capacity (TAC). Tempol, at the optimal concentration we determined that was needed to observe an antioxidant non-toxic effect in vitro (1 mM) and in vivo (200 mg/kg), completely abolished the elevation of OS markers and prevented the reduction in TAC in these areas. Importantly, tempol injections, at a dose that does not affect the basal levels of locomotor activity, attenuated both the development and expression of cocaine-induced locomotor sensitization. Finally, in cocaine-sensitized animals, tempol prevented the elevation of OS markers in both PFC and NAc. Our findings suggest that oxidation of specific sites in the brain reward system by cocaine is accompanied with behavioral changes. Tempol has a neuro-protective effect against cocaine toxicity in these regions, and it may be beneficial in the treatment of cocaine addiction.

Localization of the scaffolding protein RACK1 in the developing and adult mouse brain.

RACK1 is a multifunctional scaffolding protein known to be involved in the regulation of various signaling cascades in the central nervous system (CNS). In order to gain insight into the neurological functions of RACK1, we examined the expression of RACK1 mRNA and protein during gestation and in the adult mouse brain. Several expression patterns were observed. At embryonic day 11.5 (E11.5), RACK1 is expressed in a high-dorsal to low-ventral gradient throughout the brain. At E13.5, RACK1 is most abundant in the telencephalon. In the developing cortical primordium, RACK1 protein is expressed in a high-rostromidline to low-caudolateral gradient that appears to be regulated post-transcriptionally. At E18.5, RACK1 is expressed most abundantly in layers 1-4 of the cortex, striatum, hippocampus, dentate gyrus and specific thalamic nuclei. In the adult mouse, RACK1 is ubiquitously expressed in neuronal perikarya in most brain regions, with relatively higher levels in hippocampus, olfactory bulb, cortex and cerebellum. Subcellular staining was detected mainly in the cell bodies and extending into dendrites, whereas RACK1 was not present significantly in axonal fibers or nuclei. We also determined brain regions in which RACK1 interacts with one of its binding partners, the betaII isoform of protein kinase C (betaIIPKC). We found that betaIIPKC had a much more restricted expression pattern than RACK1 and overlapped with the scaffolding protein only in certain regions, including the CA1 area of the hippocampus, cerebellum and striatum. Our results suggest an important role for RACK1 during CNS development and support multiple functions of the protein in the adult brain.

Uncoupling of betaIIPKC from its targeting protein RACK1 in response to ethanol in cultured cells and mouse brain.

Protein kinase C (PKC) is involved in many neuroadaptive responses to ethanol in the nervous system. PKC activation results in translocation of the enzyme from one intracellular site to another. Compartmentalization of PKC isozymes is regulated by targeting proteins such as receptors for activated C kinase (RACKs). It is possible, therefore, that ethanol-induced changes in the function and compartmentalization of PKC isozymes could be due to changes in PKC targeting proteins. Here we study the response of the targeting protein RACK1 and its corresponding kinase betaIIPKC to ethanol, and propose a novel mechanism to explain how ethanol modulates signaling cascades. In cultured cells, ethanol induces movement of RACK1 to the nucleus without affecting the compartmentalization of betaIIPKC. Ethanol also inhibits betaIIPKC translocation in response to activation. These results suggest that ethanol inhibition of betaIIPKC translocation is due to miscompartmentalization of the targeting protein RACK1. Similar events occurred in mouse brain. In vivo exposure to ethanol caused RACK1 to localize to nuclei in specific brain regions, but did not affect the compartmentalization of betaIIPKC. Thus, some of the cellular and neuroadaptive responses to ethanol may be related to ethanol-induced movement of RACK1 to the nucleus, thereby preventing the translocation and corresponding function of betaIIPKC.

[Visual, auditory, and bimodal activity in the banks of the lateral suprasylvian sulcus in the cat]. / Zritel'naia, slukhovaia i bimodal'naia aktivnost' na kraiakh lateral'noi suprasil'vievoi borozdy u koshki.

In addition to visually driven cells we found within the lateral suprasylvian visual cortex of cats a considerable number of auditory and/or bimodal cells. Most of the visually driven cells were direction and orientation selective with responses that were neither highly stimulus time locked nor very stable. Most of the auditory responses were also not very stable, had relatively high thresholds and were readily habituated. Previous studies have suggested that populations of cells within the lateral suprasylvian area are specialized for the analysis of optic flow fields. Given that a remarkable proportion of cells within this area can be also driven by auditory stimuli we hypothesize that the "optic flow" model may be extended to the bimodal domain rather than restricted to visual clues only. This, however, remains to be corroborated experimentally.

Pathological and experimentally induced blindness induces auditory activity in the cat primary visual cortex.

Early blindness in humans and experimental visual deprivation in animal models are known to induce compensatory somatosensory and/or auditory activation of the visual cortex. An abnormal hydrocephalic cat with extreme malformation of the visual system, born in our breeding colony, rendered a good model system for investigating possible cross-modal compensation in such a pathological case. For comparison, we used normal and neonatally enucleated cats. When introduced to a novel environment, the abnormal cat behaved as if it was completely blind, yet it responded normally to auditory stimuli. As anticipated, single cells in the visual cortex of normal cats responded to visual, but not to auditory stimuli. In the visual cortex of enucleated cats, flashes of light did not elicit field-evoked potentials or single-unit responses. However, several cells did respond to various auditory stimuli. In the remnant visual cortex of the abnormal cat, auditory stimuli evoked field potentials and single-cell responses. Unexpectedly, however, unlike the enucleated cats, in the abnormal cat, flashes of light also elicited field-evoked potentials. Judging by its behavior, it is very likely that this deformed cat had completely lost its ability to perceive images, but had probably retained some sensitivity to light.

Auditory activation of cortical visual areas in cats after early visual deprivation.

Auditory activation of the primary visual cortex (area 17) and two extrastriate visual cortical areas - the anterolateral lateral suprasylvian area (ALLS) and anteromedial lateral suprasylvian area (AMLS), was investigated in visually impaired cats. Impairment was accomplished shortly after birth by bilateral eyelid suturing (binocularly deprived cats, BD) or bilateral enucleation (binocularly enucleated cats, BE). In BE cats, the optic nerve and chiasm were entirely degenerated. No cortical atrophy or cytoarchitectural malformation was noticed in either BD or BE cats. In both normal and impaired cats we found auditory-responsive cells in the ALLS and AMLS, areas that are considered strictly visual. The most remarkable finding was an increase in the relative number of these auditory cells in the BD and BE cats, which was more prominent in the latter. Some auditory-responsive cells were also found in area 17 of BE cats. On the basis of formal calculation, it is tempting to suggest that the increase in relative number of auditory cells in these areas reflects the transformation of all the visual cells in the ALLS of BD and BE cats into auditory cells. In BE cats, all bimodal cells and an appreciable percentage of non-responsive cells also had transformed to auditory cells. In the AMLS of BD cats, it is primarily the bimodal cells that become auditory cells, whereas in BE cats all the visual and bimodal cells as well as non-responsive cells undergo this transformation. This assumption, however, is one possible interpretation of our results but not the only one. Other modes of neuronal plasticity that might yield similar results in the visually deprived cats can not be ruled out.

NGF induces transient but not sustained activation of ERK in PC12 mutant cells incapable of differentiating.

Activation of receptor tyrosine kinases stimulates a diverse array of cellular responses such as proliferation and differentiation. The first events in the signal transduction pathways mediated by different receptor tyrosine kinases are similar and include activation of the mitogen-activated protein kinase (MAPK) pathway and the induction of immediate early genes. The precise signaling pathways leading to each of the cellular responses mediated by receptor tyrosine kinases are still unknown, although it has been proposed that sustained activation of the MAPK pathway by receptor tyrosine kinases such as the nerve growth factor (NGF) receptor TrkA is sufficient to induce differentiation in PC12 cells. In the present study we examined the effect of NGF on mutant PC12 cells that were derived spontaneously in our cultures. NGF induced normal activation of immediate early genes in these cells, whereas the activation of some delayed response genes, as well as neurite outgrowth, was impaired. Furthermore, activation of the NGF-induced extracellular signal-regulated kinase (ERK) in these cells was transient, not sustained. These results support the hypothesis that sustained activation of ERK plays an important role in activating the induction of delayed response genes. However, sustained ERK activation is not a mandatory condition for the promotion of all the features of differentiated PC12 cells, as NGF could induce transcription of the delayed response gene, transin, in PC12 mutant cells. Taken together, our results suggest that NGF induces differentiation of PC12 cells via several signaling pathways, an important one of which is the MAPK pathway.