The trade-off between pulse duration and power in optical excitation of midbrain dopamine neurons approximates Bloch's law

Optogenetic experiments reveal functional roles of specific neurons. However, functional inferences have been limited by widespread adoption of a restricted set of stimulation parameters. Broader exploration of the parameter space can deepen insight into the mapping between selective neural activity and behavior. In this way, characteristics of the activated neural circuit, such as temporal integration, can be inferred. Our objective was to determine whether an equal-energy principle accounts for the interaction of pulse duration and optical power in optogenetic excitation. Six male TH::Cre rats worked for optogenetic (ChannelRhodopsin-2) stimulation of VTA dopamine neurons. We used a within-subject design to describe the trade-off between pulse duration and optical power in determining reward seeking. Parameters were customized for each subject based on behavioral effectiveness. Within a useful range of powers (~12.6-31.6 mW) the product of optical power and pulse duration required to produce a given level of reward seeking was roughly constant. Such reciprocity is consistent with Bloch's law, which posits an equal-energy principle of temporal summation over short durations in human vision. The trade-off between pulse duration and power broke down at higher powers. Thus, optical power and duration can be adjusted reciprocally for brief durations and lower powers, and power can be substituted for pulse duration to scale the region of excitation in behavioral optogenetic experiments. The findings demonstrate the utility of within-subject and trade-off designs in optogenetics and of parameter adjustment based on functional endpoints instead of physical properties of the stimulation.

Early Adolescence is a Critical Period for the Maturation of Inhibitory Behavior

Psychiatric conditions marked by impairments in cognitive control often emerge during adolescence, when the prefrontal cortex (PFC) and its inputs undergo structural and functional maturation and are vulnerable to disruption by external events. It is not known, however, whether there exists a specific temporal window within the broad range of adolescence when the development of PFC circuitry and its related behaviors are sensitive to disruption. Here we show, in male mice, that repeated exposure to amphetamine during early adolescence leads to impaired behavioral inhibition, aberrant PFC dopamine connectivity, and reduced PFC dopamine function in adulthood. Remarkably, these deficits are not observed following exposure to the exact same amphetamine regimen at later times. These findings demonstrate that there is a critical period for the disruption of the adolescent maturation of cognitive control and PFC dopamine function and suggest that early adolescence is particularly relevant to the emergence of psychopathology in humans.

Adolescent Exposure to Methylphenidate Increases Impulsive Choice Later in Life

Background: The psychostimulant methylphenidate (MPH) is known to temporarily reduce impulsive choice and promote self-control. What is not sufficiently understood is how repeated treatment with MPH affects impulsive choice in the long run, and whether any such effect is contingent on exposure at certain developmental stages. Methods: Using an animal model for impulsive choice, we examined first whether giving MPH through early adolescence alters delay discounting, an operational measure of impulsive choice, later in adulthood. We then tested whether equivalent long-term effects are observed if exposure to the drug occurred during adulthood. Starting on postnatal day 25 or postnatal day 60, male rats received one of a range of doses of MPH for 10 consecutive days. Twenty-six days later, all rats were trained to choose between a lever that produced a small immediate reward and a lever that produced a large reward after a range of delays. Results: Rats showed a long-term decrease in the selection of the delayed larger reward when treated with moderate doses of MPH during early adolescence, but not when treated with the lower or higher doses. In contrast, no differences were observed in the selection of the delayed larger reward in animals that were treated with various doses of MPH during adulthood. Conclusions: Our findings suggest effects of MPH on impulsive choice that are contingent on dosage and on the developmental period of exposure. When administered during adolescence, moderate doses of MPH increase impulsive choice long after the end of treatment, whereas these same doses administered during adulthood were without effect.

Dampened Mesolimbic Dopamine Function and Signaling by Saturated but not Monounsaturated Dietary Lipids

Overconsumption of dietary fat is increasingly linked with motivational and emotional impairments. Human and animal studies demonstrate associations between obesity and blunted reward function at the behavioral and neural level, but it is unclear to what degree such changes are a consequence of an obese state and whether they are contingent on dietary lipid class. We sought to determine the impact of prolonged ad libitum intake of diets rich in saturated or monounsaturated fat, separate from metabolic signals associated with increased adiposity, on dopamine (DA)-dependent behaviors and to identify pertinent signaling changes in the nucleus accumbens (NAc). Male rats fed a saturated (palm oil), but not an isocaloric monounsaturated (olive oil), high-fat diet exhibited decreased sensitivity to the rewarding (place preference) and locomotor-sensitizing effects of amphetamine as compared with low-fat diet controls. Blunted amphetamine action by saturated high-fat feeding was entirely independent of caloric intake, weight gain, and plasma levels of leptin, insulin, and glucose and was accompanied by biochemical and behavioral evidence of reduced D1R signaling in the NAc. Saturated high-fat feeding was also tied to protein markers of increased AMPA receptor-mediated plasticity and decreased DA transporter expression in the NAc but not to alterations in DA turnover and biosynthesis. Collectively, the results suggest that intake of saturated lipids can suppress DA signaling apart from increases in body weight and adiposity-related signals known to affect mesolimbic DA function, in part by diminishing D1 receptor signaling, and that equivalent intake of monounsaturated dietary fat protects against such changes.

Adolescence: a time of transition for the phenotype of dcc heterozygous mice

RATIONALE

Stark differences exist between adult (>PND 70) and juvenile (∼PND 21-34) rodents in how DCC (deleted in colorectal cancer) receptors and sensitization to amphetamine interact. In adults, repeated amphetamine upregulates DCC receptor expression selectively in the ventral tegmental area (VTA), an effect that is critical for sensitization. In contrast, amphetamine administered to juveniles downregulates VTA DCC expression. Moreover, whereas adult dcc heterozygous mice fail to sensitize when repeatedly treated with amphetamine, drug treatment during the juvenile period actually abolishes this adult "protective" phenotype.

OBJECTIVES

We set out to determine whether adolescence (PND ∼35-55) is a period during which: (1) amphetamine-induced alterations in VTA DCC expression switch from downregulation to upregulation; (2) the "protective" phenotype of adult dcc heterozygotes against sensitization becomes evident; and (3) the adult "protective" phenotype of dcc heterozygotes can still be abolished by repeated amphetamine treatment.

RESULTS

Repeated amphetamine did not significantly alter VTA DCC expression in adolescent rodents when assessed 1 week later. Both wild-type and dcc heterozygous mice exhibited sensitization at this time. Remarkably, wild-type mice, but not dcc heterozygotes, exhibited sensitization when tested during adulthood.

CONCLUSIONS

Adolescence is a time of transition for dcc heterozygotes as related to sensitization. Our results support the hypothesis that DCC may be a key factor in determining age-dependent individual differences in vulnerability to sensitization. Given that exposure to drugs of abuse during adolescence can have profound consequences for adulthood, the resilience of adult dcc heterozygous mice against adolescent exposure to amphetamine is particularly salient.

Endocannabinoids promote cocaine-induced impulsivity and its rapid dopaminergic correlates

BACKGROUND

Impaired decision making, a hallmark of addiction, is hypothesized to arise from maladaptive plasticity in the mesolimbic dopamine pathway. The endocannabinoid system modulates dopamine activity through activation of cannabinoid type 1 receptors (CB1Rs). Here, we investigated whether impulsive behavior observed following cocaine exposure requires CB1R activation.

METHODS

We trained rats in a delay-discounting task. Following acquisition of stable performance, rats were exposed to cocaine (10 mg/kg, intraperitoneal) every other day for 14 days and locomotor activity was measured. Two days later, delay-discounting performance was re-evaluated. To assess reversal of impulsivity, injections of a CB1R antagonist (1.5 mg/kg, intraperitoneal) or vehicle were given 30 minutes before the task. During the second experiment, aimed at preventing impulsivity rather than reversing it, CB1Rs were antagonized before each cocaine injection. In this experiment, subsecond dopamine release was measured in the nucleus accumbens during delay-discounting sessions before and after cocaine treatment.

RESULTS

Blockade of CB1Rs reversed and prevented cocaine-induced impulsivity. Electrochemical results showed that during baseline and following disruption of endocannabinoid signaling, there was a robust increase in dopamine for immediate large rewards compared with immediate small rewards, but this effect reversed when the delay for the large reward was 10 seconds. In contrast, dopamine release always increased for one-pellet options at minimal or moderate delays in vehicle-treated rats.

CONCLUSIONS

Endocannabinoids play a critical role in changes associated with cocaine exposure. Cannabinoid type 1 receptor blockade may thus counteract maladaptive alterations in afferents to dopamine neurons, thereby preventing changes in dopaminergic activity underlying a loss of self-control.

Differential sensitivity to the acute and sensitizing behavioral effects of methylphenidate as a function of strain in adolescent and young adult rats

Background

Behavioral effects of stimulant drugs are influenced by non-pharmacological factors, including genetic variability and age. We examined acute and sensitized locomotor effects of methylphenidate in adolescent and early adult male Sprague Dawley (SD), spontaneously hypertensive (SHR) and Wistar Kyoto (WKY) rats using a drug regimen that differentiates clearly between initial and enduring differences in drug responsiveness. We probed for strain and age differences in the sensitizing effects of methylphenidate using a cocaine challenge. Methylphenidate was administered to the rats in a non-home environment.

Findings

Strain differences in sensitivity to single methylphenidate injections depend on age and change with continuing drug pretreatment. While SHR rats are more sensitive to methylphenidate relative to WKY regardless of age and pretreatment day, SHR rats become more sensitive to methylphenidate than SD rats towards the end of pretreatment during early adulthood. SD rats exhibit greater sensitivity to methylphenidate relative to the WKY group during adolescence, an effect that dissipates with continued drug pretreatment during adulthood. Remarkably, only SHR rats, regardless of age, exhibit methylphenidate-induced cross-sensitization to the behavioral effects of cocaine.

Conclusions

Our findings suggest that SHR rats are more vulnerable than other strains to methylphenidate-induced cross-sensitization to cocaine, at least when methylphenidate is administered in a non-home environment. Given that SHR rats are typically used to model features of attention deficit hyperactivity disorder, these findings may have important implications for the treatment of this disorder with methylphenidate.

High levels of wheel running protect against behavioral sensitization to cocaine

Although there is no doubt that the direct action of stimulant drugs on the brain is necessary for sensitization to their behavioral stimulating effects, several experiments indicate that drug action is often not sufficient to produce sensitization. There is considerable evidence that many individual characteristics and experiential variables can modulate the behavioral and neural changes that are seen following repeated exposure to stimulant drugs. In the work presented here, we examined whether chronic wheel running would modulate behavioral sensitization to cocaine, and whether any such influence was contingent on individual differences in wheel running. We found that a 5- or 10-week experience with wheel running protects against behavioral sensitization to cocaine but only in animals with a natural tendency to run the most. Understanding the mechanism underlying the modulating effect of wheel running on behavioral sensitization may have important implications for future studies on the link between drug-induced behavioral and neural adaptations.

The reinforcement mountain: allocation of behavior as a function of the rate and intensity of rewarding brain stimulation

The single-operant matching law has been used to describe the relationship between time allocated to pursuit of brain stimulation reward (BSR) and the obtained rate of reinforcement. We generalize this relationship to a third dimension by including the strength of the stimulation (the number of pulses per train) as an independent dimension, and we dub the resulting 3-dimensional structure "the reinforcement mountain." The validity of generalizing the single-operant matching law in this way was assessed by determining the changes in the position of the mountain produced by increasing the stimulation current or the train duration. Most of the predictions were supported, and the mountain model fitted the data closely. It is argued that application of this model can remove ambiguity inherent in 2-dimensional descriptions of operant performance and can reveal whether lesions, drugs, or physiological manipulations that alter performance for BSR act before or after the output of the ("reward-growth") function that translates the electrically induced impulse flow into the intensity of the BSR.

Predictable and unpredictable rewards produce similar changes in dopamine tone

Unpredicted rewards trigger more vigorous phasic responses in midbrain dopamine (DA) neurons than predicted rewards. However, recent evidence suggests that reward predictability may fail to influence DA signaling over longer scales: In rats passively receiving rewarding electrical brain stimulation, the concentration of DA in dialysate obtained from nucleus accumbens probes was similar regardless of whether reward onset was predictable (G. Hernandez et al., 2006). The present experiment followed up on these findings by requiring the rats to work for the rewarding stimulation, thus confirming whether they indeed learned the timing and predictability of reward delivery. Performance under fixed-interval and variable-interval schedules was compared, and DA levels in the nucleus accumbens were measured by means of in vivo microdialysis. The observed patterns of operant responding indicate that the rats working under the fixed-interval schedule learned to predict the time of reward availability, whereas the rats working under the variable-interval schedule did not. Nonetheless, indistinguishable changes in DA concentration were observed in the 2 groups. Thus, reward predictability had no discernable effect on a measure believed to track the slower components of DA signaling.

Netrin-1 receptor-deficient mice show enhanced mesocortical dopamine transmission and blunted behavioural responses to amphetamine

The mesocorticolimbic dopamine (DA) system is implicated in neurodevelopmental psychiatric disorders including schizophrenia but it is unknown how disruptions in brain development modify this system and increase predisposition to cognitive and behavioural abnormalities in adulthood. Netrins are guidance cues involved in the proper organization of neuronal connectivity during development. We have hypothesized that variations in the function of DCC (deleted in colorectal cancer), a netrin-1 receptor highly expressed by DA neurones, may result in altered development and organization of mesocorticolimbic DA circuitry, and influence DA function in the adult. To test this hypothesis, we assessed the effects of reduced DCC on several indicators of DA function. Using in-vivo microdialysis, we showed that adult mice that develop with reduced DCC display increased basal DA levels in the medial prefrontal cortex and exaggerated DA release in response to the indirect DA agonist amphetamine. In contrast, these mice exhibit normal levels of DA in the nucleus accumbens but significantly blunted amphetamine-induced DA release. Concomitantly, using conditioned place preference, locomotor activity and prepulse inhibition paradigms, we found that reduced DCC diminishes the rewarding and behavioural-activating effects of amphetamine and protects against amphetamine-induced deficits in sensorimotor gating. Furthermore, we found that adult DCC-deficient mice exhibit altered dendritic spine density in layer V medial prefrontal cortex pyramidal neurones but not in nucleus accumbens medium spiny neurones. These findings demonstrate that reduced DCC during development results in a behavioural phenotype opposite to that observed in developmental models of schizophrenia and identify DCC as a critical factor in the development of DA function.

Dopamine tone increases similarly during predictable and unpredictable administration of rewarding brain stimulation at short inter-train intervals

Unpredicted rewards, but not predicted ones, trigger strong phasic changes in the firing rates of midbrain dopamine (DA). In contrast, neurochemical measurements of DA tone have failed to reveal an influence of reward predictability. However, the subjects of the neurochemical experiments were asked to predict reward onset over longer intervals (12s, on average) than the subjects of the electrophysiological studies (typically, 2s). Thus, the contrasting effects of reward predictability could reflect the difference in the duration of the interval separating the predictor from the reward rather than a difference in the influence of reward predictability on phasic and tonic DA signaling. This hypothesis was tested in rats receiving trains of rewarding electrical brain stimulation with either a predictable or unpredictable onset. The mean inter-train interval was 1.5s, a value close to the 2-s CS-US interval that has been used in electrophysiological studies demonstrating the dependence of phasic DA responses on reward predictability. Despite the shortened inter-train interval, the time courses of the observed stimulation-induced elevations in DA levels were very similar, regardless of whether train onset was predictable. This finding is consistent with the idea that tonic DA signaling is insensitive to the predictability of rewards.

Prolonged rewarding stimulation of the rat medial forebrain bundle: neurochemical and behavioral consequences

Extracellular dopamine levels were measured in the rat nucleus accumbens by means of in vivo microdialysis. Delivery of rewarding medial forebrain bundle stimulation at a low rate (5 trains/min) produced a sustained elevation of dopamine levels, regardless of whether train onset was predictable. When the rate of train delivery was increased to 40 trains/min, dopamine levels rose rapidly during the first 40 min but then declined toward the baseline range. The rewarding impact of the stimulation was reduced following prior delivery of stimulation at the high, but not the low, rate. These results support the idea that dopamine tone plays an enabling role in brain stimulation reward and is elevated similarly by predictable and unpredictable stimulation.

Differential behavioral and neurochemical effects of cocaine after early exposure to methylphenidate in an animal model of attention deficit hyperactivity disorder

We used a putative animal model of attention deficit hyperactivity disorder (ADHD), the SHR rat, to examine the effects of repeated exposure to methylphenidate (MPH; Ritalin) during the pubertal period on cocaine-induced conditioned place preference and dopamine (DA) levels in the nucleus accumbens (NAc) in adulthood. Our results indicate that early exposure to methylphenidate diminishes sensitivity to the incentive properties of cocaine in adulthood, but it does so without altering the response of the mesolimbic dopamine system.

A role for affect in context-dependent sensitization to amphetamine

Repeated exposure to stimulant drugs, such as amphetamine, induces sensitization to their behavioral activating effects. It is commonly assumed that behavioral sensitization is expressed in the environment explicitly paired with the drug but not in a different environment explicitly unpaired with the drug. The experiments reported here show that this assumption is incorrect. It was found that sensitization was expressed in an environment explicitly unpaired with amphetamine, but imbued with positive affective valence by its association with a natural reward, oral sucrose. These results suggest that the affective valence of the environment in which the drug is administered plays a decisive role in the expression of drug effects, regardless of any previous association of that environment with the drug.

Elevated expression of 5-HT1B receptors in nucleus accumbens efferents sensitizes animals to cocaine

Although the effects of psychostimulants on brain dopamine systems are well recognized, the direct actions of cocaine on serotonin systems also appear to be important to its addictive properties. For example, serotonin actions at 5-HT1B receptors in the ventral tegmental area (VTA) modulate cocaine-induced dopamine release in the nucleus accumbens (NAcc) and alter the rewarding and stimulant properties of cocaine. However, the mechanisms of these effects have been unclear, because several neuron types in VTA express 5-HT1B receptors. One possibility is that 5-HT1B receptors on the terminals of GABAergic projections from NAcc to VTA inhibit local GABA release, thereby disinhibiting VTA neurons. We tested this hypothesis directly by using viral-mediated gene transfer to overexpress 5-HT1B receptors in NAcc projections to VTA. A viral vector containing either epitope hemagglutinin-tagged 5-HT1B and green fluorescent protein (HA1B-GFP) cassettes or green fluorescent protein cassette alone (GFP-only) was injected into the NAcc shell, which sends projections to the VTA. HA1B-GFP injection induced elevated expression of 5-HT1B receptors in neuronal fibers in VTA and increased cocaine-induced locomotor hyperactivity without affecting baseline locomotion. Overexpression of 5-HT1B receptors also shifted the dose-response curve for cocaine-conditioned place preference to the left, indicating alterations in the rewarding effects of cocaine. Thus, increased expression of 5-HT1B receptors in NAcc efferents, probably in the terminals of medium spiny neurons projecting to the VTA, may contribute to psychomotor sensitization and offer an important target for regulating the addictive effects of cocaine.

Light suppresses Fos expression in the shell region of the suprachiasmatic nucleus at dusk and dawn: implications for photic entrainment of circadian rhythms

The transcription factor Fos is implicated in neuronal signaling in the suprachiasmatic nucleus, the mammalian circadian clock (Ikonomov and Stoynev, 1994; Klein et al., 1991; Kornhauser et al., 1996). Fos is expressed in two different regions within the suprachiasmatic nucleus. In the ventrolateral, retinorecipient, core region (Leak et al., 1999; Moga and Moore, 1997), Fos is induced by light and expression is closely linked, both temporally and functionally, to clock resetting and entrainment of circadian rhythms (Aronin et al., 1990; Beaulé and Amir, 1999; Hastings et al., 1995; Kornhauser et al., 1996; Kornhauser et al., 1990; Rea, 1989, 1998; Rusak et al., 1990; Wollnik et al., 1995). In the dorsomedial shell region (Leak et al., 1999), Fos expression is rhythmic (Guido et al., 1999a,b; Rusak et al., 1992; Sumova and Illnerova, 1998; Sumova et al., 1998). Expression is high during the subjective day when photic sensitivity of the core is minimal, and low in the subjective night, when photic sensitivity of the core is maximal. Although it has been shown that the pattern of Fos expression in the shell tracks the photoperiod (Sumova et al., 2000), nothing is known about whether light influences the expression of Fos in the shell region or about the role of Fos expression in the shell in clock resetting and entrainment. In the present study we found that, in rats maintained in constant darkness, brief exposure to light in the early subjective day or night induced Fos in the core, as expected, and acutely suppressed the levels of Fos immunoreactivity in the shell region. Similar changes in Fos expression in the core and shell regions were seen after exposure to a brief entraining light. Light exposure in the mid-subjective day or night differentially affected Fos expression in the core, as previously shown, but had no effect on Fos expression in the shell region. The finding that Fos expression in the shell region of the suprachiasmatic nucleus is suppressed by light at dawn and dusk suggests a critical role for the shell in photic entrainment of circadian rhythms in nocturnal rodents.

Altered responsiveness to cocaine in rats exposed to methylphenidate during development

Evidence in laboratory animals indicates that exposure to stimulants produces sensitization to their rewarding effects, a process that in humans would be expected to increase the risk of substance abuse. However, therapeutic administration of stimulants such as methylphenidate (MPH) in children with attention deficit hyperactivity disorder reportedly reduces the risk of substance abuse. Here we show in rats that exposure to MPH during pre-adolescence causes behavioral and neurobiological adaptations that endure into adulthood, and that are consistent with increased sensitivity to the aversive effects of cocaine.

A novel, associative process modulating photic resetting of the circadian clock

Appropriate timing of physiological and behavioral processes requires that the circadian clock be reset daily by salient cues in the environment, particularly light. It is known that the ability of light to reset the clock depends both on its intensity and on the circadian time when it is applied (Daan and Pittendrigh, 1976; Moore-Ede et al., 1982). Here we show that the ability of a weak light stimulus to reset the clock is dramatically enhanced when it is presented daily at the same circadian time. Equivalent daily presentations of this light stimulus, but at different circadian times each day, do not lead to such enhancement. These findings suggest that the ability of light to reset the clock can be modified through a novel, and previously unrecognized, conditioning-like associative process in which circadian time serves as the conditioned stimulus and light as the unconditioned stimulus. The idea that circadian time can serve as a conditioned stimulus to modulate the effectiveness of light provides a new perspective on the lasting impact that light schedules have on the circadian clock and, thus, may have implications for existing models of photic entrainment (Pittendrigh and Daan, 1976; Moore-Ede et al., 1982).

Time acts as a conditioned stimulus to control behavioral sensitization to amphetamine in rats

Repeated exposure to the psychostimulant drug, amphetamine, results in a persistent increase in the ability of the drug to elicit behavioral activation.(14,19) The development of sensitized responses to amphetamine involves long-lasting neuroadaptations within defined circuitry.(3,6,12,15,23) The behavioral expression of sensitization, however, can come under the control of specific environmental cues. Thus, the sensitized locomotor response to a challenge injection of amphetamine is greater if the drug is given in the environment previously associated with intermittent injections than if given in a different environmental context.(2,13,16,18,20,21) Contrary to the wealth of information on the significance of contextual cues, little is known about the importance of time cues in the expression of sensitized responding to amphetamine. In the present study we, therefore, asked whether time of injection might influence the expression of amphetamine sensitization. We found that time can readily act as a conditioned stimulus to control the expression of behavioral sensitization to amphetamine in rats. This finding is important for understanding the mechanisms underlying sensitization to psychostimulant drugs and its impact on behavior.

Calbindin-D28k immunoreactivity in the suprachiasmatic nucleus and the circadian response to constant light in the rat

Recent studies in the hamster have led to the discovery that the expression of the calcium binding protein, calbindin-D28k, is a defining feature of neurons in the suprachiasmatic nucleus involved in the regulation of circadian rhythms by environmental light.(2,18, 19,32) To study further the involvement of calbindin-D28k, we examined the effect of exposure to constant light on calbindin-D28k immunoreactivity in the suprachiasmatic nucleus of intact rats and of rats treated neonatally with the retinal neurotoxin, monosodium glutamate. Exposure to constant light is known to disrupt circadian rhythms in rodents and we found previously that treatment with monosodium glutamate selectively prevents the disruptive effect of constant light on circadian rhythms in rats.(7,9) In the present study we found that exposure to light suppresses calbindin-D28k expression in the ventrolateral retinorecipient region of the suprachiasmatic nucleus of rats and that neonatal treatment with monosodium glutamate blocks the suppressive effect of constant light on calbindin-D28k expression. These findings are consistent with the proposed role of calbindin-D28k in photic signaling in the suprachiasmatic nucleus,(32) and point to the possibility that suppression of calbindin-D28k expression is linked to the mechanism by which constant light disrupts circadian rhythms.

Fos expression following self-stimulation of the medial prefrontal cortex

Self-stimulation of the medial prefrontal cortex and medial forebrain bundle appears to be mediated by different directly activated fibers. However, reward signals from the medial prefrontal cortex do summate with signals from the medial forebrain bundle, suggesting some overlap in the underlying neural circuitry. We have previously used Fos immunohistochemistry to visualize neurons activated by rewarding stimulation of the medial forebrain bundle. In this study, we assessed Fos immunolabeling after self-stimulation of the medial prefrontal cortex. Among the structures showing a greater density of labeled neurons in the stimulated hemisphere were the prelimbic and cingulate cortex, nucleus accumbens, lateral preoptic area, substantia innominata, lateral hypothalamus, anterior ventral tegmental area, and pontine nuclei. Surprisingly, little or no labeling was seen in the mediodorsal thalamic nucleus or the locus coeruleus. Double immunohistochemistry for tyrosine hydroxylase and Fos showed that within the ventral tegmental area, a substantial proportion of dopaminergic neurons did not express Fos. Despite previous suggestions to the contrary, comparison of the present findings with those of our previous Fos studies reveals a number of structures activated by rewarding stimulation of both the medial prefrontal cortex and the medial forebrain bundle. Some subset of activated cells in the common regions showing Fos-like immunoreactivity may contribute to the rewarding effect produced by stimulating either site.

Conditioned stimulus control in the rat circadian system depends on clock resetting during conditioning

The authors examined the ability of a conditioned stimulus (CS; mild air disturbance) previously paired with an entraining light pulse to reset the circadian pacemaker in rats. Rats were entrained to a single 30-min light stimulus delivered every 25 hr or 24 hr (T cycle). Each daily light presentation was paired with the CS. After at least 20 days of stable entrainment to each of the T cycles, the rats were allowed to free run and were then presented with the CS at circadian time 15. CS-induced phase shifts in wheel-running activity rhythms were taken as evidence for conditioning. For the most part, conditioning occurred after CS-light pairings on the 25-hr but not 24-hr T cycle. The results suggest that CS control of the circadian clock phase depends on the effect that the entraining light pulse has on the clock during conditioning.

Early onset of demyelination after N-methyl-D-aspartate lesions of the lateral hypothalamus

The function of neurons residing in a particular brain area is often assessed by injecting glutamatergic excitotoxins into that area and determining the consequences for the behavior of interest. However, injections of excitotoxins into the central nervous system not only kill local neurons but also demyelinate fibers of passage. Previous studies suggest that the myelin damage is triggered by a delayed inflammatory response to cell death mediated by monocytes of peripheral origin. If so, demyelination should commence only after recruitment of monocytes, their passage through the blood-brain barrier, and their metamorphosis into macrophages. This process is estimated to require at least 48 h. Using a hematoxylin (Weil) stain and immunohistochemistry for myelin basic protein, we looked for signs of demyelination at various times after injections of N-methyl-D-aspartate into the lateral hypothalamus. Demyelination was seen within 24 h after the lesion, sooner than predicted by the monocytic infiltration hypothesis. This finding has implications for interpreting effects of excitotoxic lesions and for developing means of improving their specificity.

Resetting the rat circadian clock by ultra-short light flashes

We examined the effects that ultra-brief, intense, light flashes have on the rat circadian clock, the suprachiasmatic nucleus of the hypothalamus (SCN). We found that as few as five intense flashes, each 10-micros in duration (1 per s), can produce both phase shifts in free-running activity rhythms and Fos expression in the SCN in rats kept in constant darkness. After pre-exposure to such flashes, phase shifts in response to a continuous light pulse delivered 2 h later were potentiated, but Fos expression in the SCN was decreased as following pre-exposure to continuous light. These results show that flashes induce behavioral and cellular effects indicative of clock resetting similar to those induced by light stimuli of longer duration. Extremely brief but intense, light stimuli may be much more important to clock resetting than had been previously known.

Effects of NMDA lesions of the medial basal forebrain on LH and VTA self-stimulation

Rewarding stimulation of the medial forebrain bundle (MFB) increases Fos-like immunoreactivity in many brain areas, including an ipsilateral, basal forebrain region extending from the medial preoptic area (MPO) to the lateral preoptic area, and substantia innominata. Excitotoxic lesions of the lateral portion of this region have been found to produce large sustained or transient increases in the number of pulses required to maintain half-maximal lever-pressing (required number of pulses) for MFB stimulation. In the present study, changes in self-stimulation of the lateral hypothalamus and ventral tegmental area were assessed following excitotoxic lesions of more medial structures, including the MPO and bed nucleus of the stria terminalis. Increases in the required number of pulses (up to 0.16 log10 units) were seen in only 2 of 10 subjects. In two other rats, the reward effectiveness of the stimulation was moderately increased after the lesion as manifested in decreases of up to 0.14 log10 units in the required number. No appreciable change from baseline was seen in the remaining six subjects. The simplest interpretation of these results is that neurons with cell bodies in the medial portion of the basal forebrain may make a smaller contribution to the rewarding effect of MFB stimulation than neurons in the lateral portion.

Fos-like immunoreactivity in the caudal diencephalon and brainstem following lateral hypothalamic self-stimulation

Fos immunohistochemistry was used to stain neurons in the caudal diencephalon, midbrain and hindbrain driven by rewarding stimulation of the lateral hypothalamus (LH). Increases in Fos-like immunoreactivity were most pronounced ipsilateral to the site of stimulation and tended to be confined within discrete structures such as the posterior LH, arcuate nucleus, ventral tegmental area (VTA), central gray, dorsal raphé, pedunculopontine area (PPTg), parabrachial nucleus, and locus coeruleus. At least two of these structures, the VTA and PPTg, have been implicated in medial forebrain bundle self-stimulation.

Fos-like immunoreactivity in forebrain regions following self-stimulation of the lateral hypothalamus and the ventral tegmental area

According to the descending-path hypothesis, the direct excitation of descending fibers linking the lateral hypothalamus (LH) and ventral tegmental area (VTA) contributes to the rewarding effect produced by electrical stimulation of the medial forebrain bundle (MFB). To visualize forebrain neurons activated by stimulation of both the LH and VTA, Fos-like immunoreactivity (FLIR) in forebrain regions was assessed following self-stimulation of these two sites in male rats. Among the regions where FLIR was greater in the stimulated hemisphere following either LH or VTA stimulation were the anterior LH, the substantia innominata, and the bed nucleus of the stria terminalis, and olfactory tubercle. These findings are analyzed with reference to the effects of forebrain lesions on self-stimulation of the MFB. Advantages and limitations of using FLIR to identify neurons activated by rewarding stimulation are discussed.

Increased ipsilateral expression of Fos following lateral hypothalamic self-stimulation

Immunohistochemical labeling of Fos protein was used to visualize neurons activated by rewarding stimulation of the lateral hypothalamic level of the medial forebrain bundle (MFB). Following training and stabilization of performance, seven rats were allowed to self-stimulate for 1 h prior to anesthesia and perfusion. Brains were then processed for immunohistochemistry. Two control subjects were trained and tested in an identical manner except that the stimulator was disconnected during the final 1 h test. Among the structures showing a greater density of labeled neurons on the stimulated side of the brains of the experimental subjects were the septum, lateral preoptic area (LPO), medial preoptic area, bed nucleus of the stria terminalis, substantia innominata (SI), and the lateral hypothalamus (LH). Several of these structures, the LPO, SI, and LH, have been implicated in MFB self-stimulation by the results of psychophysical, electrophysiological, and lesion studies.

Effects of excitotoxic lesions of the basal forebrain on MFB self-stimulation

Electrolytic lesions of the anterior medial forebrain bundle (MFB) have been shown to attenuate the rewarding impact of stimulating more caudal MFB sites. In the present study, excitotoxic lesions were employed to determine the relative contribution of somata or fibers of passage contributing to that effect. Changes in reward efficacy were inferred, at three currents, from lateral displacements of the curve relating the rate of responding to the number of stimulation pulses per train. After baseline data were collected from stimulation sites in the lateral hypothalamus (LH) and the ventral tegmental area (VTA), 70 nmol of N-methyl-D-aspartic acid was injected via cannulae aimed at basal forebrain sites. Three subjects were injected with vehicle and served as controls. In 5 out of 15 cases, lesions encompassing the lateral preoptic area, anterior LH, and substantia innominata resulted in long-lasting, large increases (0.2-0.47 log10 units) in the number of pulses required to maintain half-maximal rates of self-stimulation for low currents delivered via the LH electrode; smaller increases (0.08-0.33 log10 units) were noted at moderate and high currents. Seven rats with similar or more dorsally located damage showed moderate or transient increases in the number of pulses required to maintain half-maximal rates of LH or VTA self-stimulation. Vehicle injections did not affect behaviour. Varying degrees of demyelination were seen, mostly removed from the electrode tip, and in locations that varied substantially across subjects manifesting similar changes in self-stimulation. These results support the notion that somata in the basal forebrain give rise to some of the directly activated fibers subserving self-stimulation of the MFB.