Effects of pergolide on sensorimotor gating of the startle reflex in rats.

RATIONALE: Prepulse inhibition (PPI), a cross-species measure of sensorimotor gating, is impaired in certain neuropsychiatric disorders, including schizophrenia. This study was designed to assess the effects of the D2-family agonist pergolide in rats, in anticipation of human studies of the dopaminergic regulation of PPI. METHODS: The effects of pergolide (0.0001-0.5 mg/kg) on PPI of the acoustic startle reflex were studied in rats using a wide range of prepulse intensities [1-15 dB(A) over background] and prepulse intervals (5-100 ms, onset to onset). Studies also examined the effects of the D2 antagonist haloperidol on pergolide-induced changes in PPI. RESULTS: Pergolide exhibited dose- and stimulus-dependent effects on PPI. Pergolide increased PPI when startle stimuli were preceded by weak prepulses [1-5 dB(A) over background] at the longest prepulse interval (100 ms), or intense prepulses [15 dB(A) over background] at short prepulse intervals (5-20 ms). Pergolide (0.5 mg/kg) also decreased PPI elicited by intense prepulses at long intervals (60-100 ms). Both PPI-enhancing and PPI-disruptive effects of pergolide were reversed by the D2 antagonist haloperidol. CONCLUSIONS: These effects of pergolide suggest that D2 substrates mediate opposing influences on PPI under different stimulus conditions. The dopaminergic regulation of sensorimotor gating appears to interact with stimulus characteristics such as relative intensity and temporal separation, allowing for dynamic shifts in both the quantity and quality of "gated" information.

Sensitivity to the dopaminergic regulation of prepulse inhibition in rats: evidence for genetic, but not environmental determinants.

Prepulse inhibition (PPI), a measure of sensorimotor gating, is reduced in schizophrenia patients and in rats treated with dopamine (DA) agonists. Reported strain and supplier-based differences in sensitivity to PPI-disruptive effects of DA agonists presumably reflect the differential impact of genetics and/or environment on DAergic substrates regulating PPI. In 2000, Harlan Laboratories established a Texas Sprague-Dawley line (SDHt; facility 211) using breeders from Indianapolis (SDHi; facility 202A). SDHi rats had been used, approximately 11 years earlier, to establish a colony in San Diego (SDHsd; facility 235). SDHt and SDHi rats are thus genetically similar, but raised in distinct environments; approximately 11 years of genetic "drift" separates SDHsd rats from both SDHi and SDHt rats. Harlan Long-Evans hooded rats (LEH; Madison, WI; facility 207) are genetically distinct from albino SDH. All except SDHsd rats were shipped to our facility by air freight. We used SDHt, SDHi, SDHsd, and LEH rats to assess genetic and environmental contributions to the DAergic regulation of PPI. Acoustic startle/PPI were assessed in rats treated with the D1/D2 agonist apomorphine (APO), the D2 agonist quinpirole, or the D1 agonist SKF 82958. The relative sensitivities to the PPI-disruptive effects were: APO: SDHt=SDHsd=SDHi>>LEH; SKF 82958: SDHt=SDHsd=SDHi (LEH not sensitive); quinpirole: SDHt=SDHsd=SDHi; SDHi>LEH. Strain/supplier differences in sensitivity to drug effects on startle magnitude did not correspond to patterns of PPI sensitivity. In these rats, strain differences in the DAergic regulation of PPI are most easily explained by genetic, rather than environmental influences that differentially impact both D1 and D2 substrates. This finding is consistent with published reports in other strains. Pharmacogenetic studies of PPI in rats may identify a genetic basis for a model of deficient sensorimotor gating in schizophrenia.

Lesion size and amphetamine hyperlocomotion after neonatal ventral hippocampal lesions: more is less.

Neonatal hippocampal lesions in rats produce behavioral and neurochemical abnormalities post-puberty that are used in animal models for developmentally linked pathology in schizophrenia. In one model, adult rats exhibit enhanced sensitivity to the locomotor-activating effects of amphetamine, if they had sustained excitotoxic lesions of the ventral hippocampus on post-natal day 7. The hippocampal elements responsible for these lesion-induced developmental changes have not been fully characterized. The present study assessed the locomotor-activating effects of amphetamine in adult rats that on day 7 had sustained either sham or ibotenic acid lesions of the ventral hippocampus alone ("standard lesions"), or the ventral hippocampus plus surrounding portions of entorhinal cortex and dorsal hippocampus ("large lesions"). "Standard lesions" produced the expected "supersensitive" locomotor response to amphetamine, while "large lesions" did not. No differences between these lesion groups were observed in baseline levels of locomotor activity or habituation. These data suggest that models of enhanced behavioral sensitivity to dopamine agonists after neonatal hippocampal lesions require functionality in the entorhinal cortex and/or dorsal hippocampus. It is possible that the behavioral abnormalities in the "neonatal hippocampal lesion model" reflect, at least in part, aberrant function within spared elements of the hippocampal complex.

Toward understanding the biology of a complex phenotype: rat strain and substrain differences in the sensorimotor gating-disruptive effects of dopamine agonists.

Sensorimotor gating, measured by prepulse inhibition (PPI) of the startle reflex, is reduced in schizophrenia patients and in rats treated with dopamine agonists. Strain differences in the sensitivity to the PPI-disruptive effects of dopamine agonists may provide insight into the genetic basis for human population differences in sensorimotor gating. We reported strain differences in the sensitivity to the PPI-disruptive effects of the D1/D2 agonist apomorphine in adult rats, with greater sensitivity in Harlan Sprague Dawley (SDH) versus Wistar (WH) rats. However, Kinney et al. (1999) recently reported opposite findings, using Bantin-Kingman Sprague Dawley (SDBK) and Wistar (WBK) rats; in fact, SDBK rats did not exhibit clear apomorphine-induced reductions in sensorimotor gating. These new findings of Kinney et al. (1999) directly conflict with over 15 years of results from our laboratories and challenge interpretations from a large body of literature. The present studies carefully assessed drug effects on sensorimotor gating in SD versus W strains, across rat suppliers (H vs BK). Significantly greater SDH than WH apomorphine sensitivity in PPI measures was observed in both adult and 18 d pups, confirming that these strain differences are both robust and innate. These strain differences in apomorphine sensitivity were not found in adult BK rats. Supplier differences in sensitivity (SDH > SDBK) were also evident in the PPI-disruptive effects of D1 but not D2-family agonists; PPI was clearly disrupted by quinpirole in both SDH and SDBK rats. These findings demonstrate robust, innate, neurochemically specific, and apparently heritable phenotypic differences in an animal model of sensorimotor gating deficits in human neuropsychiatric disorders.