The relationship between clinically effective antipsychotic drug dosage and binding affinity to cloned dopamine (DA) and serotonin receptor subtypes was analyzed in an effort to elucidate the contribution of individual receptor subtypes to medication response. Clinically effective dose and binding affinity to D 2 DA receptor were modestly correlated for typical antipsychotic medications (r ¼ 0.
The D3 dopamine receptor is expressed primarily in limbic brain areas, and appears to play an inhibitory role in rodent locomotor behavior. Evidence suggests a potential role for the D3 receptor in the pathology of neuropsychiatric disease. Progress in elucidating D3 receptor function has been hampered, however, by a lack of well-characterized, selective ligands and by conflicting information regarding the behavioral phenotype of D3 receptor knockout mice. Here, we describe studies evaluating the behavioral effects of ( 7 )-7-hydroxy-N,N-di-n-propyl-2-aminotetralin (7-OH-DPAT) and PD 128907, two D3 receptor agonists whose in vivo selectivity has been a topic of considerable controversy. We demonstrate that both compounds inhibit locomotion under novel environmental conditions in wild-type (WT) mice, but are without measurable behavioral effect under identical conditions in D3 receptor knockout mice. Additionally, we demonstrate that at low, D3 selective doses, these compounds are without behavioral effect in both WT and D3 receptor knockout mice that have acclimated to the testing environment. These findings suggest that D3 receptor stimulation inhibits novelty-stimulated locomotion, and establish conditions for the use of 7-OH-DPAT and PD 128907 as D3 receptor agonists in vivo. Potential implications of these observations are discussed.
Long-standing behavioral abnormalities emerge after puberty in rats following neonatal hippocampal lesion, providing a developmental model of abnormal rat behavior that may have predictive validity in identifying compounds effective in treating symptoms of schizophrenia. We sought to test the predictive validity of the neonatal hippocampal lesion model in identifying preventive treatment for first-episode psychosis. We determined the effect of risperidone, recently studied for prevention of first-episode psychosis, on the development of elevated locomotor activity following neonatal hippocampal lesions. Rat pups received hippocampal or sham lesions on postnatal day 7, followed by treatment with risperidone or vehicle from postnatal days 35 to 56. Locomotor activity in response to novelty, amphetamine, and nocturnal locomotion were determined on postnatal day 57. Low-dose risperidone (45 mg/kg) pretreatment prevented elevated locomotor activity in some, but not all, of the behavioral tasks following neonatal hippocampal lesions. In contrast, higher risperidone pretreatment was less effective in preventing elevated locomotor activity following neonatal hippocampal lesions. Because low risperidone dosages were also found to be effective in preventing first-episode psychosis in human studies, these data support the predictive validity of the hippocampal lesion model in identifying medications for prevention of first-episode psychosis. Additionally, these data support the use of low-dose risperidone in psychosis prevention, and suggest the possibility that higher risperidone doses could be less effective in this application.
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