Assessment of reward responsiveness in the response bias probabilistic reward task in rats: implications for cross-species translational research.

Mood disorders, such as major depressive disorder, are characterized by abnormal reward responsiveness. The Response Bias Probabilistic Reward Task (hereafter referred to as probabilistic reward task (PRT)) quantifies reward responsiveness in human subjects, and an equivalent animal assessment is needed to facilitate preclinical translational research. Thus, the goals of the present studies were to develop, validate and characterize a rat analog of the PRT. Adult male Wistar and Long-Evans rats were trained in operant testing chambers to discriminate between two tone stimuli that varied in duration (0.5 and 2 s). During a subsequent test session consisting of 100 trials, the two tones were made ambiguous (0.9 and 1.6 s) and correct identification of one tone was reinforced with a food pellet three times more frequently than the other tone. In subsequent experiments, Wistar rats were administered either a low dose of the dopamine D2/D3 receptor agonist pramipexole (0.1 mg kg(-1), subcutaneous) or the psychostimulant amphetamine (0.5 mg kg(-1), intraperitoneal) before the test session. Similar to human subjects, both rat strains developed a response bias toward the more frequently reinforced stimulus, reflecting robust reward responsiveness. Mirroring prior findings in humans, a low dose of pramipexole blunted response bias. Moreover, in rats, amphetamine potentiated response bias. These results indicate that in rats, reward responsiveness can be quantified and bidirectionally modulated by pharmacological manipulations that alter striatal dopamine transmission. Thus, this new procedure in rats, which is conceptually and procedurally analogous to the one used in humans, provides a reverse translational platform to investigate abnormal reward responsiveness across species.

Neonatal maternal separation exacerbates the reward-enhancing effect of acute amphetamine administration and the anhedonic effect of repeated social defeat in adult rats.

Early life adversity or parental neglect is linked to the development of a number of psychiatric illnesses, including major depression and substance use disorder. These two disorders are often comorbid and characterized by anhedonia, defined as the reduced ability to experience pleasure or reward. The aim of the present study was to determine the effects of neonatal maternal separation in Long Evans rats, a model of early life stress, on anhedonia under baseline conditions and in response to drug and stress exposure during adulthood. Three hours of daily maternal separation from postnatal day 1 to 14 led to marked decreases in arched-back nursing, licking, and grooming of pups by their dams. In adulthood, brain reward function was assessed using intracranial self-stimulation of the lateral hypothalamus. Lowered current thresholds derived from this procedure are interpreted as reward-enhancing effects, whereas elevations in thresholds are an operational measure of anhedonia. Maternally separated rats did not exhibit anhedonia under baseline conditions compared with non-handled controls but exhibited a greater reward-enhancing effect of acute amphetamine administration. Acute social defeat produced anhedonia in non-handled controls, but not in maternally separated rats. Conversely, control rats habituated to 7 days of repeated social defeat, whereas maternally separated rats developed an increased anhedonic response to the repeated stressor. One week after termination of stress exposure, maternally separated rats still exhibited an increased reward-enhancing effect of acute amphetamine administration compared with non-handled controls, regardless of prior social defeat experience. These data indicate that early life stress increases the reward-enhancing properties of amphetamine, protects against the anhedonic effects of acute stress exposure, and exacerbates the anhedonic response to repeated stress. Thus, early life stress may increase an individual's vulnerability to depressive or addictive disorders when confronted with stress or drug challenge in adulthood.

Stress potentiation of morphine-induced dopamine efflux in the nucleus accumbens shell is dependent upon stressor uncontrollability and is mediated by the dorsal raphe nucleus.

A single session of uncontrollable (inescapable tailshock, IS), but not controllable (escapable tailshock, ES), stress is known to selectively potentiate subsequent morphine-conditioned place preference in a dorsal raphe nucleus (DRN) serotonin (5-HT) dependent manner. Here, in vivo microdialysis is used to test the hypothesis that prior IS, but not ES, will potentiate morphine-induced dopamine (DA) efflux in the nucleus accumbens (NAc) shell and that this will occur by a pathway involving DRN 5-HT neurons. Male Sprague-Dawley rats were exposed to yoked IS, ES, or no stress. Twenty-four hours later, morphine (3 mg/kg s.c.) or saline was administered during microdialysis. As predicted, prior IS selectively potentiated morphine-induced DA, but not 5-HT, efflux in the NAc. This potentiation was due to morphine's action in the DRN because it was blocked by intra-DRN microinjection of the opioid antagonist naltrexone (10 microg). IS potentiation of morphine-induced DA efflux in the NAc was also dependent upon activation of 5-HT neurons in the DRN because it was blocked by intra-DRN microinjection of the 5-HT1A autoreceptor agonist 8-hydroxy-2-di-n-(propylamino)-tetralin (1 microg). No effect of IS was found on morphine-induced 5-HT or DA efflux in the ventral tegmental area. These results suggest a neural substrate for stress potentiation of morphine reward involving 5-HT neurotransmission in the DRN.

Targeted disruption of Hoxd9 and Hoxd10 alters locomotor behavior, vertebral identity, and peripheral nervous system development.

The five most 5' HoxD genes, which are related to the Drosophila Abd-B gene, play an important role in patterning axial and appendicular skeletal elements and the nervous system of developing vertebrate embryos. Three of these genes, Hoxd11, Hoxd12, and Hoxd13, act synergistically to pattern the hindlimb autopod. In this study, we examine the combined effects of two additional 5' HoxD genes, Hoxd9 and Hoxd10. Both of these genes are expressed posteriorly in overlapping domains in the developing neural tube and axial mesoderm as well as in developing limbs. Locomotor behavior in animals carrying a double mutation in these two genes was altered; these alterations included changes in gait, mobility, and adduction. Morphological analysis showed alterations in axial and appendicular skeletal structure, hindlimb peripheral nerve organization and projection, and distal hindlimb musculature. These morphological alterations are likely to provide the substrate for the observed alterations in locomotor behavior. The alterations observed in double-mutant mice are distinct from the phenotypes observed in mice carrying single mutations in either gene, but exhibit most of the features of both individual phenotypes. This suggests that the combined activity of two adjacent Hox genes provides more patterning information than activity of each gene alone. These observations support the idea that adjacent Hox genes with overlapping expression patterns may interact functionally to provide patterning information to the same regions of developing mouse embryos.