Faculty Bibliography

Many laboratories have reported that systemically administered naloxone has little or no effect on lateral hypothalamic self-stimulation (LH ICSS). In the present study, lateral ventricular infusion of beta-endorphin antiserum and a high dose of naloxone (100 micrograms) produced small but significant increases in stimulation frequency threshold for LH ICSS. beta-Endorphin activity, mediated by a non-mu (e.g. delta or epsilon) receptor, may therefore be involved in the reinforcement of self-stimulation behavior. When rats are deprived of food for 24 h, LH ICSS thresholds decline. Under this condition, systemic naloxone elevates the LH ICSS threshold, often returning it to the pre-deprivation level. In the present study, lateral ventricular infusion of dynorphin A(1-13) antiserum similarly reversed the threshold-lowering effect of food deprivation. The effects of systemic naloxone and intraventricular dynorphin A antiserum on LH ICSS, which are specific to food-deprived animals, may be related to previous findings that these two treatments elevate LH stimulation threshold for eliciting feeding behavior. Results of the ICSS and stimulation-induced feeding studies suggest a model for the mediation of incentive stimuli by dynorphin A activity that is afferent to LH 'reward' neurons and positively gated by 'hunger'. An hypothesized role for 'hunger'-gated dynorphin A release in potentiating the hedonic response to alimentary stimuli and drugs of abuse is discussed

Although opioid antagonists block feeding behavior in a variety of animal models, the number and identity of CNS regions in which the inferred endogenous opioid activity mediates feeding have yet to be established. Furthermore, it is not yet clear whether the opioid activity that sustains feeding is a concomitant of the appetitive motivational state or the consummatory response. In an effort to address these issues, an in vivo autoradiographic method was used to visualize CNS regional changes in opioid release during appetitively motivating electrical stimulation in the lateral hypothalamus (ESLH) and during consummatory behavior elicited by such stimulation. Regional decreases in [3H]diprenorphine [(3H]Dpr) binding, suggesting increased release of an endogenous opioid peptide, were observed in the medial prefrontal cortex, medial septum, gustatory cortex, zona incerta, mediodorsal thalamus, and hippocampus of rats receiving ESLH. Decreased binding in the latter 4 structures did not appear when animals were allowed to eat during ESLH, suggesting that the inferred opioid release is associated with appetitive behaviors elicited by ESLH which are suppressed when food is available and consummatory behavior predominates. When animals were allowed to eat during ESLH, [3H]Dpr binding in anterior cingulate cortex decreased substantially, suggesting that feeding behavior specifically triggers opioid release in this region. ESLH and feeding were found to increase [3H]Dpr binding in a number of CNS regions. Alternative explanations for increased binding, including inhibition of tonic opioid release, changes in cerebral blood flow, and opioid receptor up-regulation are discussed

Lateral ventricular injection of antibodies to dynorphin A(1-13) was previously shown to elevate lateral hypothalamic stimulation frequency threshold for eliciting feeding behavior. The antibodies utilized in that study cross-react completely with dynorphin A(1-17) and, to a lesser extent, dynorphin A(1-8). In the present study, highly specific antibodies to dynorphin A(1-17) and dynorphin A(1-8) were infused into the lateral ventricle and mesopontine aqueduct to determine which biologically active dynorphin A fragment mediates feeding and at what level of the CNS this activity is likely to occur. Both antibodies were found to elevate the feeding threshold. Dynorphin A(1-8) antibodies were effective at both injection sites while dynorphin A(1-17) antibodies were only effective at the lateral ventricular site. These findings suggest that feeding-related dynorphin A(1-17) activity may occur predominantly within the forebrain, while dynorphin A(1-8) activity occurs within the brainstem. Only the dynorphin A(1-8) antibodies, infused into the aqueduct, produced a naloxone-like pattern of progressive elevation in serially determined thresholds; this pattern was previously interpreted to reflect a reduction in consummatory reward. Dynorphin A(1-8) activity within some brainstem structure(s) may therefore contribute prominently to the opioid mechanism whose mediation of the hedonic response to food was previously inferred from naloxone antagonism.