Stephen Fairhurst

Transient Overexpression of Striatal D2 Receptors Impairs Operant Motivation and Interval Timing

The striatum receives prominent dopaminergic innervation that is integral to appetitive learning, performance, and motivation. Signaling through the dopamine D2 receptor is critical for all of these processes. For instance, drugs with high affinity for the D2 receptor potently alter timing of operant responses and modulate motivation. Recently, in an attempt to model a genetic abnormality encountered in schizophrenia, mice were generated that reversibly overexpress D2 receptors specifically in the striatum (Kellendonk et al., 2006). These mice have impairments in working memory and behavioral flexibility, components of the cognitive symptoms of schizophrenia, that are not rescued when D2 overexpression is reversed in the adult. Here we report that overexpression of striatal D2 receptors also profoundly affects operant performance, a potential index of negative symptoms. Mice overexpressing D2 exhibited impairments in the ability to time food rewards in an operant interval timing task and reduced motivation to lever press for food reward in both the operant timing task and a progressive ratio schedule of reinforcement. The motivational deficit, but not the timing deficit, was rescued in adult mice by reversing D2 overexpression with doxycycline. These results suggest that early D2 overexpression alters the organization of interval timing circuits and confirms that striatal D2 signaling in the adult regulates motivational process. Moreover, overexpression of D2 under pathological conditions such as schizophrenia and Parkinsons disease could give rise to motivational and timing deficits.

Effects of dopamine antagonists on the timing of two intervals.

Rats were trained on a two-interval (12 and 36 s) temporal production task (the peak procedure). Test sessions were conducted in which either the D(1) antagonist SCH-23390 (SCH; 0.02, 0.04, 0.06 mg/kg) or the D(2) antagonist haloperidol (HAL; 0.05, 0.1, 0.2 mg/kg) were injected prior to testing. Both drugs affected the amount of responding, but only HAL affected timing. Under HAL, both intervals were overestimated, consistent with a HAL-induced decrease in clock speed. Drug-induced decreases in response output were more profound for the long interval than the short. In addition, there was evidence of HAL- and SCH-induced delays in response initiation that were more severe for the long interval, perhaps owing to its status as a weaker conditioned stimulus.

Dawn and dusk simulation as a therapeutic intervention.

Daily alternations of light and darkness entrain circadian rhythms of body tem~rature, rest-activity, and melatonin and other neuroendocrine secretions (cf., Moore-Ede et al. 1982). Annual cycles of changing light-dark patterns underlie seasonal metabolic and behavioral cycles and, in humans living distant from the equator, a syndrome of winter depression with prominent atypical neurovegetative symptoms of fatigue, hypersomnia, carbohydrate craving, and weight gain (Rosenthal et al. 1984). Affected individuals suffer annual cycles of spontaneous relapse and remission, generally in autumn and spring, respectively. Early-morning artificial bright light (>2000 lux) provides effective treatment in this variant of depression (Rosenthal et al. 1985; Lewy and Sack 1986; Terman 1988), while also inducing immediate suppression of n~tumal melatonin secretion (Lewy et al. 1980), and within several days, circadian phase shifts (Lewy et al. 1985; Terman et al. 1988). In humans, normal indoor illumination levels (<800 Iux) have proven

Pharmacologic Rescue of Motivational Deficit in an Animal Model of the Negative Symptoms of Schizophrenia

BACKGROUND Deficits in incentive motivation, the energizing of behavior in pursuit of a goal, occur in many psychiatric disorders including schizophrenia. We previously reported deficits in both cognition and incentive motivation in a transgenic mouse model of increased striatal-specific dopamine D2 receptor (D2R) density (D2R-OE mice). This molecular alteration is observed in patients with schizophrenia, making D2R-OE mice a suitable system to study the cellular and molecular mechanisms of motivation and avolition, as well as a tool for testing potential therapies against motivational deficits. METHODS Behavioral studies using operant conditioning methods were performed both to further characterize the incentive motivation deficit in D2R-OE mice and test a novel pharmacological treatment target that arose from an unbiased expression study performed using gene chips and was validated by quantitative reverse transcription polymerase chain reaction, in situ hybridization, and immunohistochemistry. RESULTS The reluctance of D2R-OE mice to work is due neither to intolerance for low rates of reward, decreased reactivity to reward, nor increased sensitivity to satiety or fatigue but to a difference in willingness to work for reward. As in patients with schizophrenia, this deficit was not ameliorated by D2R blockade, suggesting that reversal of the motivational deficit by switching off the transgene results from molecular changes downstream of D2R overexpression. We observed a reversible increase in serotonin subtype 2C (5-HT2C) receptor expression in D2R-OE mice. Systemic injection of a 5-HT2C receptor antagonist increased incentive motivation in D2R-OE and control mice. CONCLUSIONS We propose that targeting 5-HT2C receptors may be a useful approach to modulate incentive motivation in psychiatric illness.

Impaired Timing Precision Produced by Striatal D2 Receptor Overexpression is Mediated by Cognitive and Motivational Deficits

Increased striatal dopamine D2 receptor activity is thought to contribute to the pathophysiology of schizophrenia. To model this condition in mice, Kellendonk et al. (2006) generated transgenic mice that selectively overexpress the D2 receptor in striatum (D2OE). Drew et al. (2007) reported that D2OE mice display deficits in interval timing and motivation. The present study further explored the impaired timing in D2OE mice. Experiment 1 assessed the role of motivation in producing timing deficits in the peak procedure and found that performance in D2OE mice was improved by increasing motivation. In addition, performance was impaired in control mice when motivation was decreased. In Experiment 2, we found that D2OE mice have no timing impairment when tested using the bisection task, a procedure in which the measure of timing performance is less influenced by motivation to respond. In Experiment 3, we also used the bisection task and found selective impairment in timing of long durations in D2OE mice. These results suggest that striatal D2 overexpression impairs timing by decreasing motivation and through its impact on working memory and/or sustained attention.

Glutaminase-Deficient Mice Display Hippocampal Hypoactivity, Insensitivity to Pro-Psychotic Drugs and Potentiated Latent Inhibition: Relevance to Schizophrenia

Dysregulated glutamatergic neurotransmission has been strongly implicated in the pathophysiology of schizophrenia (SCZ). Recently, presynaptic modulation of glutamate transmission has been shown to have therapeutic promise. We asked whether genetic knockdown of glutaminase (gene GLS1) to reduce glutamatergic transmission presynaptically by slowing the recycling of glutamine to glutamate, would produce a phenotype relevant to SCZ and its treatment. GLS1 heterozygous (GLS1 het) mice showed about a 50% global reduction in glutaminase activity, and a modest reduction in glutamate levels in brain regions relevant to SCZ pathophysiology, but displayed neither general behavioral abnormalities nor SCZ-associated phenotypes. Functional imaging, measuring regional cerebral blood volume, showed hippocampal hypometabolism mainly in the CA1 subregion and subiculum, the inverse of recent clinical imaging findings in prodromal and SCZ patients. GLS1 het mice were less sensitive to the behavioral stimulating effects of amphetamine, showed a reduction in amphetamine-induced striatal dopamine release and in ketamine-induced frontal cortical activation, suggesting that GLS1 het mice are resistant to the effects of these pro-psychotic challenges. Moreover, GLS1 het mice showed clozapine-like potentiation of latent inhibition, suggesting that reduction in glutaminase has antipsychotic-like properties. These observations provide further support for the pivotal role of altered glutamatergic synaptic transmission in the pathophysiology of SCZ, and suggest that presynaptic modulation of the glutamine–glutamate pathway through glutaminase inhibition may provide a new direction for the pharmacotherapy of SCZ.

Daily Meal Anticipation: Interaction of Circadian and Interval Timing

Both short-interval and circadian timing systems support anticipatory response accelerations prior to food reinforcement. In the first case, the behavior pattern is determined by a scalar timing process with an arbitrary-reset property. In contrast, under daily cycles of food-availability, behavior reflects a self-sustaining oscillation. With rats as subjects, the concurrent operation of timing of both kinds was studied by addition of premeal auditory cues on the circadian baseline, in the absence of a day-night illumination cycle. Cues within both minute and hour ranges served to lower the level of premeal anticipatory responding, although exponential accelerations were similar to the uncued case. Cues within the minutes range yielded interval-timing functions that reflected approximate superposition. Cues within the hours range suppressed respondings at their outset, in proportion to cue duration. When one of the shorter cues was suddenly lengthened, short-interval accelerations appeared at inappropriate circadian phases. When a premeal cue was extended through mealtime, anticipation rates increased markedly, suggesting that cue termination at the start of mealtime is a potent anchor for premeal anticipation regardless of cue duration. By use of meal-omission probes without external cues, peak rates were located after the onset of expected mealtime, often near its termination. The results suggest interactions between the scalar interval timer and the circadian anticipation timer, as modulated by the circadian free-run timer.

Chapter 8 Cooperation, conflict and compromise between circadian and interval clocks in pigeons

Publisher Summary This chapter summarizes some of the properties of interval timing systems and circadian timing systems, and then describes an experiment studying interval timing in the hours range embedded in circadian food anticipation timing. The two systems are put in cooperative or conflicting roles by manipulation of time of day, and/or cue onsets for interval timing, and the results of these manipulations are seen to involve a compromise between the two timing systems. The chapter reports an experimental study of two pigeons, living in isolation chambers for several years. The experiments designed illuminate several problems. It appears that behavior in the hours range cues exhibit the hallmark property of interval timing, the scalar superposition finding in relative time. In addition to the differences noted above between hours range timing and seconds to minutes range timing, timing in the hours range raises the issue of redundancy with circadian, time of day (TOD) mechanisms for anticipating feedings. Such mechanisms have been documented in the hours range.

Mnemonics for variability: remembering food delay.

Three experiments with White Carneaux pigeons (Columba livia) investigated memory and decision processes under fixed and variable reinforcement intervals. Response rate was measured during the unreinforced trials in the discrete-trial peak procedure in which reinforced trials were mixed with long unreinforced trials. Two decision models differing in assumptions about memory constraints are reviewed. In the complete-memory model (J. Gibbon, R.M. Church, S. Fairhurst, & A. Kacelnik, 1988), all interreinforcement intervals were remembered, whereas in the minimax model (D. Brunner, A. Kacelnik, & J. Gibbon, 1996), only estimates of the shortest and longest possible reinforcement times were remembered. Both models accommodated some features of response rate as a function of trial time, but only the second was compatible with the observed cessation of responding.

Pavlovian contingencies and temporal information

The effects of altering the contingency between the conditioned stimulus (CS) and the unconditioned stimulus (US) on the acquisition of autoshaped responding was investigated by changing the frequency of unsignaled USs during the intertrial interval. The addition of the unsignaled USs had an effect on acquisition speed comparable with that of massing trials. The effects of these manipulations can be understood in terms of their effect on the amount of information (number of bits) that the average CS conveys to the subject about the timing of the next US. The number of reinforced CSs prior to acquisition is inversely related to the information content of the CS.