The role of Rhes, Ras homolog enriched in striatum, in neurodegenerative processes.

Rhes is a small GTPase whose expression is highly enriched in striatum. It shares homology with Ras proteins, but also contains a C-terminal extension, thus suggesting additional functions. Signaling by 7 transmembrane receptors through heterotrimeric G proteins is inhibited by Rhes. However, perhaps the most remarkable feature of this small GTPase described thus far is that it can account for the selective vulnerability of the striatum in Huntington's Disease (HD). HD is an autosomal dominant neurodegenerative disease caused by a poly-glutamine expansion in the protein huntingtin. Despite the presence of huntingtin throughout the brain and the rest of the body, the striatum is selectively degenerated. Recent work shows that Rhes acts as an E3 ligase for attachment of SUMO (small ubiquitin-like modifier). As this post-translational modification decreases the formation of huntingtin aggregates and promotes cell death, this property of Rhes offers an explanation for selective striatal vulnerability in HD. In addition, the sequestering of Rhes through its binding to mutant huntingtin may decrease the ability of Rhes to perform vital physiological functions in the neuron. Thus, as Rhes is an attractive candidate for HD therapy, a thorough understanding of its physiological functions will allow for specific targeting of its pathological functions.

Attenuation of Rhes activity significantly delays the appearance of behavioral symptoms in a mouse model of Huntington's disease.

Huntington's disease (HD) is a neuropsychiatric disorder characterized by choreiform movement of the limbs, cognitive disability, psychosis and dementia. It is invariably associated with an abnormally long CAG expansion within the IT15 gene on human chromosome 4. Although the mutant huntingtin protein is ubiquitously expressed in HD patients, cellular degeneration occurs predominantly in neurons within the corpus striatum and cerebral cortex. The Ras homolog Rhes is expressed very selectively in the precise brain areas affected by HD. Recent in vitro work suggests that Rhes may be a co-factor with mutant huntingtin in cell death. The objective of the present study was to examine whether the inhibition of Rhes would attenuate or delay the symptoms of HD in vivo. We used a transgenic mouse model of HD crossed with Rhes knockout mice to show that the behavioral symptoms of HD are regulated by Rhes. HD(+)/Rhes(-/-) mice showed significantly delayed expression of HD-like symptoms in this in vivo model. Drugs that block or inhibit the actions of Rhes may be useful as the first treatments for HD.

Mice lacking rhes show altered morphine analgesia, tolerance, and dependence.

Rhes, the Ras Homolog Enriched in Striatum, is an intermediate-size GTP binding protein. Although its full functions are not yet known, it has been shown to affect signaling and behaviors mediated by G protein-coupled receptors. Here we have tested whether Rhes affects behaviors mediated by opioid receptors. Wild type and rhes-deficient mice were administered morphine and tested for analgesia in formalin and tail flick tests. Rhes⁻/⁻ mice showed significantly enhanced analgesia in both tests relative to rhes+/+ mice. Furthermore, rhes⁻/⁻ mice did not display tolerance to repeated morphine administration and displayed significantly less withdrawal than rhes+/+ mice. These findings indicate that Rhes is involved in behaviors mediated by mu opioid receptors and in the adaptive response to repeated morphine administration.

Reduced-volume cues effectively support fear conditioning despite sleep deprivation.

Sleep deprivation impairs contextual but not cued learned fear, and it has been suggested that this pattern reflects an insensitivity of the amygdala to sleep loss. The lack of effect of sleep deprivation on cued conditioning, however, might simply be due to the strong attention drawn by the typically loud cue tone. We reduced tone volume from our standard 80 dB to either 70 or 60 dB, to test if reduced cue volume allowed effects of sleep deprivation to be detected. Using the platform-over-water method, male C57BL/6 mice were sleep-deprived for 24 h; control mice were moved to novel cages for 24 h. Mice then underwent fear conditioning with a standard "delay" protocol, and were tested for contextual and cued learning the next day. A control group received no footshock during conditioning. In the cue test, and for both cue volumes, SD had no effect on freezing to the tone, which was very robust in conditioned mice regardless of sleep treatment. As expected, freezing to the tone in the no-shock groups was essentially absent. Also, freezing prior to the tone was low in all mice. At the lowest volume, the tone was only ~10 dB above background noise. 24 h sleep deprivation, however, blocked contextual fear in the same mice. These results support a pattern of sleep deprivation sparing amygdaloid function but impairing hippocampal function.

Chronic menthol attenuates the effect of nicotine on body temperature in adolescent rats.

Menthol is a commonly used additive in tobacco products. Smoking cessation may be more difficult for smokers of mentholated cigarettes, particularly adolescent smokers. Evidence indicates that menthol can influence neurotransmitter receptors and nicotine metabolism. We investigated the effects of chronic menthol using body temperature as a bioassay for the effects of acute nicotine in vivo. Male rats (34-36 days, adolescent; 53-58 days, young adult; 9-10 months, full adult) were injected with menthol (100 mg/kg) or vehicle once daily for 4 days. On day 5, animals were injected with nicotine (0.5 mg/kg) and body temperature was measured for the next 70 min. We found no effect of chronic menthol treatment or of age on baseline temperature. Nicotine quickly produced vasodilatory hypothermia in all animals. Chronic menthol treatment had significant effects only in adolescent rats, diminishing nicotine-induced hypothermia. Nicotine treatment was repeated on day 6 to test for tolerance. Equivalent tolerance was found in all ages, and the attenuating effect of menthol was still present and was still limited to adolescent rats. In adolescents, acute menthol injection (400 mg/kg) 30 min prior to nicotine also attenuated nicotine-induced hypothermia but with a smaller effect size. Also in adolescents, we found no effect of chronic or acute menthol on hypothermia induced by hydralazine, a peripherally acting vasodilator. These data demonstrate that menthol diminishes the influence of nicotine on body temperature in adolescents, suggesting a greater susceptibility of youthful physiology to menthol.

The Ras homolog Rhes affects dopamine D1 and D2 receptor-mediated behavior in mice.

Dopamine activates five different receptor subtypes and a complex array of intracellular signaling pathways. Rhes is a striatally expressed guanidine triphosphate-binding protein involved in dopamine signaling. Here we have used mutant mice to test whether Rhes (Ras homolog enriched in striatum) is involved in D1 and D2 dopamine receptor-mediated behaviors. Rhes was not necessary for the expression of normal D1/D2 receptor synergism, as measured by apomorphine-induced stereotypy. The stereotypic responses to D1/D2 costimulation and to D2 stimulation alone were significantly increased in mice lacking Rhes, but D1 receptor-mediated grooming was reduced in these mice. These results suggest that Rhes is normally inhibitory to behaviors induced by D1/D2 receptor costimulation and by D2 receptor stimulation alone. Rhes, however, seems to facilitate the D1-specific behavior of grooming.

Ontogeny and dopaminergic regulation in brain of Ras homolog enriched in striatum (Rhes).

Rhes is one of several signaling molecules preferentially expressed in the striatum. This GTP-binding protein affects dopamine-mediated signaling and behavior. Denervating the striatum of its dopaminergic inputs in adulthood reduces rhes mRNA expression. Here we show that dopamine depletion in adult rats by 6-hydroxydopamine caused a significant decrease in striatal Rhes protein levels as measured by Western blotting. The role of dopamine input on rhes mRNA induction during ontogeny was also examined. Rhes mRNA was measured on postnatal days 4, 6, 8, 10, 15, and 24 with in situ hybridization to determine its normal ontogeny. Signal in striatum was detectable, but very low, on postnatal day 4 and increased gradually to peak levels at days 15 and 24. Outside of the striatum, rhes mRNA was expressed at high levels in hippocampus and cerebellum during the postnatal period. Hippocampal signal was initially highest in CA3 and dentate gyrus, but shifted to higher expression in CA1 by the late postnatal period. Several other nuclei showed low levels of rhes mRNA during ontogeny. Depletion of dopamine by 6-hydroxydopamine injection on postnatal day 4 did not affect the ontogenetic development of rhes mRNA, such that expression did not differ statistically in lesioned versus vehicle-treated animals tested in adulthood. These findings suggest that although dopamine input is not necessary for the ontogenetic development of rhes mRNA expression, changes in both rhes mRNA and Rhes protein are integral components of the response of the adult striatum to dopamine depletion.

Aspects of learned fear related to the hippocampus are sleep-dependent.

Reduced sleep interferes with contextual but not cued learned fear, and it was suggested that this selectivity reflects underlying neural substrates. The apparent lack of contextual fear in sleep-deprived animals, however, could be secondary to hyperactivity. Also, changing the parameters of cued conditioning can change the neural pathways involved, such that some types of cued fear might be sensitive to sleep loss. To address these issues, we measured fear expressed with conditioned defecation as well as behavior, and used a trace cued learning paradigm. Using the platform-over-water method, male Sprague-Dawley rats were continuously sleep-deprived for 3 days, or for 20 h/day for 3 days. Animals then underwent fear conditioning, and were tested for learning the next day. Sleep-deprived or -restricted animals showed a lack of contextual fear at testing, as conditioned freezing and defecation were minimal. Sleep deprivation also blocked cued fear after trace conditioning. Therefore, reduced sleep impairs contextual learning, and impairs cued learning only when the hippocampus is involved. The data support a model in which sleep loss interferes with hippocampal function while sparing amygdala function.

RGS9-2 negatively modulates L-3,4-dihydroxyphenylalanine-induced dyskinesia in experimental Parkinson's disease.

Chronic L-dopa treatment of Parkinson's disease (PD) often leads to debilitating involuntary movements, termed L-dopa-induced dyskinesia (LID), mediated by dopamine (DA) receptors. RGS9-2 is a GTPase accelerating protein that inhibits DA D2 receptor-activated G proteins. Herein, we assess the functional role of RGS9-2 on LID. In monkeys, Western blot analysis of striatal extracts shows that RGS9-2 levels are not altered by MPTP-induced DA denervation and/or chronic L-dopa administration. In MPTP monkeys with LID, striatal RGS9-2 overexpression--achieved by viral vector injection into the striatum--diminishes the involuntary movement intensity without lessening the anti-parkinsonian effects of the D1/D2 receptor agonist L-dopa. In contrasts, in these animals, striatal RGS9-2 overexpression diminishes both the involuntary movement intensity and the anti-parkinsonian effects of the D2/D3 receptor agonist ropinirole. In unilaterally 6-OHDA-lesioned rats with LID, we show that the time course of viral vector-mediated striatal RGS9-2 overexpression parallels the time course of improvement of L-dopa-induced involuntary movements. We also find that unilateral 6-OHDA-lesioned RGS9-/- mice are more susceptible to L-dopa-induced involuntary movements than unilateral 6-OHDA-lesioned RGS9+/+ mice, albeit the rotational behavior--taken as an index of the anti-parkinsonian response--is similar between the two groups of mice. Together, these findings suggest that RGS9-2 plays a pivotal role in LID pathophysiology. However, the findings also suggest that increasing RGS9-2 expression and/or function in PD patients may only be a suitable therapeutic strategy to control involuntary movements induced by nonselective DA agonist such as L-dopa.

Behavioral synergism between D(1) and D(2) dopamine receptors in mice does not depend on gap junctions.

Activation of the D(1) and D(2) classes of dopamine receptor in the striatum synergistically promotes motor stereotypy. The mechanism of D(1)/D(2) receptor interaction remains unclear. To investigate the involvement of electrical synaptic transmission in this phenomenon, genetic inactivation of the neuronal gap junction (GJ) protein connexin 36 and pharmacological blockade of GJs were utilized. Stereotyped motor behavior was quantified after selective activation of D(1) receptors, D(2) receptors, or both receptors. These patterns of activation were produced by injection of the agonist apomorphine (3.0 mg/kg) 30 min after either the D(2) antagonist eticlopride (0.3 mg/kg), the D(1) antagonist SCH 23390 (0.1 mg/kg) or vehicle, respectively. Mixed background C57/BL6-129SvEv mice homozygous or heterozygous for the connexin 36 "knockout" allele displayed potent synergistic interaction between D(1) and D(2) receptor activation, and did not differ significantly from wild-type mice on any measure. All genotypes demonstrated long-lasting stereotypic sniffing, chewing, and/or licking after simultaneous activation of D(1) and D(2) receptors, effects that were absent following selective D(1) or D(2) activation. Swiss-Webster mice treated with the GJ blockers carbenoxolone (35 mg/kg), octanol (350 mg/kg) or mefloquine (50 mg/kg) also demonstrated the normal synergistic interaction between D(1) and D(2) receptors, although these drugs did block the grooming stimulated by selective D(1) receptor activation, independently of D(2) receptors. While D(1) receptor-stimulated grooming depends on GJs composed of connexins or possibly pannexins, the synergistic interaction of D(1) and D(2) receptors in control of stereotypy does not involve GJs.

Menthol and nicotine oppositely modulate body temperature in the rat.

Menthol is a prominent additive in many tobacco products. To investigate possible interactions with nicotine, (-)-menthol (200 or 400 mg/kg) and (-)-nicotine (0.5 mg/kg) were injected subcutaneously in rats, and body temperature, which is modulated by brain nicotinic acetylcholine receptors, was measured. Nicotine caused robust (-1.6 degrees C) hypothermia, the magnitude and time course of which was not altered by menthol pretreatment. Menthol alone produced mild (0.4-0.8 degrees C) hyperthermia, which was not secondary to locomotor activation. Nicotine and menthol influence body temperature independently and oppositely; menthol does not appear to influence the function of the central nicotinic receptors that control body temperature.

Altered NMDA receptor trafficking contributes to sleep deprivation-induced hippocampal synaptic and cognitive impairments.

Recent evidence indicates that continuous wakefulness (sleep deprivation, SD) causes impairments in behavioral performance and hippocampal long-term potentiation (LTP) in animals. However, the mechanisms by which SD impairs long-term synaptic plasticity and cognitive function are not clear. Here, we report that 24-h SD in mice results in impaired hippocampus-dependent contextual memory and LTP and, unexpectedly, in reductions of the surface expression of NMDA receptor (NMDAR) subunit NR1 and NMDAR-mediated excitatory post-synaptic currents at hippocampal perforant path-dentate granule cell synapses. The results suggest that the reduction of functional NMDAR in hippocampal neurons may underlie the SD-induced deficits in hippocampus-dependent contextual memory and long-term synaptic plasticity.

Eliminating the adrenal stress response does not affect sleep deprivation-induced acquisition deficits in the water maze.

Sleep deprivation impairs spatial learning in the rat. Sleep deprivation, however, also causes stress and stress itself can interfere with spatial learning. To address this confound, sleep deprivation effects on Morris water maze training were studied in intact rats and in rats in which the adrenal stress response had been eliminated by adrenalectomy. Stable, physiological levels of corticosterone were maintained in adrenalectomized rats with an implanted pellet. Training occurred 6-7 days after surgery. Seventy-two hours sleep deprivation by the platform-over-water method just prior to training slowed, but did not block, learning. In particular, the robust savings between trials 1 and 2 of the first set found in home cage rats was not present in sleep-deprived rats. Adrenalectomy/corticosterone replacement surgery did not modify the effect of sleep deprivation on acquisition rate, demonstrating that the deficits in spatial task acquisition due to pre-training sleep deprivation are not secondary to the adrenal stress response.

Sleep deprivation impairs hippocampus-mediated contextual learning but not amygdala-mediated cued learning in rats.

Prolonged sleep deprivation results in cognitive deficits. In rats, for example, sleep deprivation impairs spatial learning and hippocampal long-term potentiation. We tested the effects of sleep deprivation on learning in a Pavlovian fear conditioning paradigm, choosing a sleep deprivation paradigm in which REM sleep was completely prevented and non-REM sleep was strongly decreased. During conditioning, rats were given footshocks, either alone or paired with a tone, and tested 24 h later for freezing responses to the conditioning context, and to the tone in a novel environment. Whereas control animals had robust contextual learning in both background and foreground contextual conditioning paradigms, 72 h of sleep deprivation before conditioning dramatically impaired both types of contextual learning (by more than 50%) without affecting cued learning. Increasing the number of footshocks did not overcome the sleep deprivation-induced deficit. The results provide behavioural evidence that REM/non-REM sleep deprivation has neuroanatomically selective actions, differentially interfering with the neural systems underlying contextual learning (i.e. the hippocampus) and cued learning (i.e. the amygdala), and support the involvement of the hippocampus in both foreground and background contextual conditioning.

Sleep deprivation causes behavioral, synaptic, and membrane excitability alterations in hippocampal neurons.

Although the function of sleep remains elusive, several lines of evidence suggest that sleep has an important role in learning and memory. In light of the available data and with the prevalence of sleep deprivation (SD), we sought to determine the effect of SD on neuronal functioning. We found that the exposure of rats to 72 hr of primarily rapid eye movement SD impaired their subsequent performance on a hippocampus-dependent spatial learning task but had no effect on an amygdala-dependent learning task. To determine the underlying cellular level mechanisms of this hippocampal deficit, we examined the impact of SD on several fundamental aspects of membrane excitability and synaptic physiology in hippocampal CA1 pyramidal neurons and dentate gyrus granule cells. We found that neuronal excitability was severely reduced in CA1 neurons but not in granule cells and that the production of long-term potentiation of synaptic strength was inhibited in both areas. Using multiple SD methods we further attempted to differentiate the effects of sleep deprivation from those associated with the nonspecific stress induced by the sleep deprivation methods. Together these data suggest that failure to acquire adequate sleep produces several molecular and cellular level alterations that profoundly inhibit hippocampal functioning.

Carbamazepine reduces dopamine-mediated behavior in chronic neuroleptic-treated and untreated rats: implications for treatment of tardive dyskinesia and hyperdopaminergic states.

Chronic treatment with neuroleptic drugs such as haloperidol (HAL) can result in a syndrome of abnormal involuntary movements known as tardive dyskinesia (TD). The authors have obtained evidence that TD in humans is reduced in patients also taking anticonvulsant drugs, primarily carbamazepine (CBZ). To test for a causal role of CBZ in this effect, the authors quantified abnormal movements elicited by dopamine (DA) receptor stimulation in rats (Rattus norvegius) withdrawn from chronic treatment with HAL or CBZ alone or in combination. The expected increased behavioral responsiveness to combined D1/D2 stimulation in rats treated with HAL for 8 weeks was significantly attenuated by chronic CBZ, which also attenuated behavioral responsiveness in otherwise untreated rats. Striatal D2 DA receptor density was elevated in rats treated chronically with HAL but unaffected by CBZ. Striatal D1 DA receptor density was elevated by chronic CBZ but unaffected by HAL. These findings suggest that by reducing DA supersensitivity, CBZ may be useful in treating TD and other hyperdopaminergic states.