The development of kindled seizures is accelerated in the genetically epilepsy-prone rat

The kindling phenomenon was examined in genetically epilepsy-prone (GEPR) and non-epileptic control Sprague-Dawley rats. Kindling stimulations were administered three times a day until each rat had exhibited three Class 5 kindled motor seizures. The mean total number of kindling stimulations required for each experimental group to exhibit three motor seizures of each motor seizure class was determined. The results indicated that the early stage of kindling development was accelerated significantly in both the GEPR-3 and GEPR-9 rats, compared to non-epileptic control rats. Later stages of kindling development were accelerated in GEPR-9 but not GEPR-3 rats. Thus a differential acceleration of kindling development was exhibited by GEPR-3 and GEPR-9 rats. The results suggest the possibility that some brain region(s) involved in the early stages of kindling development may be hyperexcitable in both GEPR-3 and GEPR-9 rats. Other brain region(s) involved with the later stages of kindling development may be more excitable in GEPR-9 rats. These putative alterations may, in part, contribute to the seizure prone state of GEPR rats and the differential seizure responses of GEPR-3 and GEPR-9 rats.     

Serotonergic abnormalities in the central nervous system of seizure-naive genetically epilepsy-prone rats.

Seizure predisposition in Genetically Epilepsy-Prone Rats (GEPRs) is characterized by abnormal sensitivity to a number of seizure provoking stimuli. The GEPR model is composed of two independently derived colonies with each exhibiting a characteristic convulsive pattern. In response to a standardized sound stimulus, GEPR-3s exhibit moderate or clonic convulsions while GEPR-9s exhibit more severe tonic extensor convulsions. In order to further characterize the neurochemical abnormalities that underlie seizure predisposition in GEPRs, the current study examined serotonin concentrations in 14 discrete brain areas of controls, GEPR-3s and GEPR-9s. In all areas examined, serotonin concentrations were lower in either one or both GEPR types than in seizure resistant controls. In 6 of the 14 areas both GEPR-3s and GEPR-9s had levels significantly lower than controls. In an additional 7 areas GEPRs had serotonin concentrations of similar magnitude which were significantly lower than control when the GEPR values were combined. In cerebellum, GEPR-3s had significantly lower serotonin concentration than either controls of GEPR-9s while in the striatum, GEPR-9s had significantly lower serotonin levels than either GEPR-3s or controls. In summary, GEPRs have widespread deficits in serotonin concentration and that these abnormalities appear to contribute to the seizure predisposition that characterizes these animals.     

Responsiveness of genetically epilepsy-prone rats to intracerebroventricular morphine-induced convulsions

The sensitivity to intracerebroventricular morphine-induced convulsions was determined in members of the severe seizure (GEPR-9) and moderate seizure (GEPR-3) colonies of genetically epilepsy-prone rats as well as in non-epileptic control rats. GEPR-9s were more sensitive to morphine-induced wet-dog shakes, rearing with bilateral forelimb clonus and generalized clonus than controls of GEPR-3s. GEPR-3s were less sensitive to morphine-induced wet-dog shakes and rearing with bilateral forelimb clonus than controls. Both high and extremely low doses of morphine in GEPR-9s elicited tonic extensor convulsions resembling the characteristic sound-induced convulsion of GEPR-9s. The results suggest that opiotergic systems may contribute to the pathophysiology of the seizure-prone condition in GEPR-9s. Further, differences in responsiveness of opiotergic systems in GEPR-3s and GEPR-9s may partially account for differences in seizure severity in the characteristic sound-induced seizures of these two types of GEPRs.     

Anticonvulsant drugs and the genetically epilepsy-prone rat

Anticonvulsant drugs were evaluated in members of two colonies of genetically epilepsy-prone rats (GEPR). Virtually all of the animals in the first colony experience a wild running fit that terminates in a generalized clonic convulsion when they are stimulated by sound. According to our convulsion intensity scoring system, these animals have an audiogenic response score (ARS) of 3 and the colony is designated the GEPR-3 colony. In the second colony, more than 95% of the animals experience a wild running phase terminating in a tonic extensor convulsion when they are stimulated by sound. That is, they have an ARS of 9 and the colony is designated the GEPR-9 colony. All of the established antiepileptic drugs that were tested produced anticonvulsant effects in the GEPR. Three tricyclic antidepressant agents acted as anticonvulsants in doses substantially lower than the toxic doses that produced spontaneous convulsions. Two of the established anticonvulsants, phenobarbital and ethosuximide, produced anticonvulsant effects in very similar doses in members of GEPR-3 and GEPR-9 colonies. Valproic acid produced an anticonvulsant effect in GEPR-3 in significantly lower doses than in GEPR-9. Carbamazepine, phenytoin, imipramine, amitriptyline, and desipramine produced anticonvulsant effects in essentially equimolar doses and in each case the protective dose was significantly lower in GEPR-9 than in GEPR-3 colonies. GEPR did not experience the convulsive effects of imipramine, amitriptyline, and desipramine at lower doses than did control animals. Thus, these epilepsy-prone animals are no more likely to experience convulsions in response to overdose of one of these three drugs than are nonepileptic subjects.     

Evidence of immunosuppression in the genetically epilepsy-prone rat

Immune system function was examined in the genetically epilepsy prone (GEPR-9) rat and non-epileptic Sprague-Dawley control rats. Significant decreases in direct and indirect plaque-forming cell responses were observed in GEPR-9 rats immunized with sheep erythrocytes. Serum levels of IgM were also decreased in non-immunized GEPR-9 rats, providing additional evidence of immunosuppression. However, total serum levels of IgG were three-fold greater in GEPR-9 rats compared to control. These results suggest that the nature of the immune system deficit in the GEPR-9 is complex and may involve an active T-cell population stimulating an overproduction of IgG leading to a diminished capacity to respond to new antigen challenges. This immunological defect may underlie the enhanced susceptibility of GEPR-9 rats to infectious agents. The specific cause of this immune dysfunction is not known. Possible etiological factors include a breakdown in the communication between cells within the immune system or an alteration of neuroendocrine modulation of immune responses.     

Anatomical changes of the GABAergic system in the inferior colliculus of the genetically epilepsy-prone rat

The number of GABAergic neurons as determined by GAD immunocytochemistry and total neurons as determined from Nissl preparations were counted and classified at the light microscopic level in the inferior colliculus (IC) of the genetically epilepsy prone rat (GEPR) and the non-epileptic Sprague-Dawley (SD) strain of rat. GAD-positive neurons are abundant in the IC and a significant increase in the number of GAD-positive neurons occurs in the GEPR as compared to the SD in all three subdivisions. However, the most pronounced difference occurs in the ventral lateral portion of the central nucleus, where there is a selective increase in the small (200%) and medium-sized (90%) GABAergic somata (10-15 microns in diameter and 15-25 microns in diameter, respectively). As determined from Nissl preparations an increase in total numbers of neurons also occurs. Thus, a 100% increase in the number of small neurons and a 30% increase in the number of medium-sized neurons occur in the adult GEPR as compared to the SD rat. A statistically significant increase in the numbers of small neurons also occurred in the IC of the young GEPR. At 4 days of age, a 55% increase in the number of small neurons was found, and at 10 days of age this increase was 105%. The numbers of the medium and large neurons were similar in the older group of rats. These data suggest that the increase in cell number observed in the adult GEPR is not compensatory to the seizure activity, but may either be genetically programmed or be a failure of cell death. Based on other studies of genetic models of epilepsy, we propose that the additional GABAergic neurons may disinhibit excitatory projection neurons in the IC.     

Cerebral cortical GABA and benzodiazepine binding sites in genetically seizure prone rats

Adult male and female genetically seizure-prone rats were assessed for sound-induced seizures. Heterozygous control groups were compared with mild seizure (designated GEPR 3) and severe seizure animals (GEPR 9). Groups of animals were killed and crude synaptosome fractions (P2) prepared from freshly dissected cerebral cortices. Binding sites for gamma-aminobutyric acid (GABA) were assessed by [3H]-muscimol in the absence or presence of excess GABA and/or pentobarbital. Binding sites for benzodiazepines were assessed by [3H]-flunitrazepam in the presence or absence of clonazepam. Compared to controls, GEPR 3 animals had a modest increase and GEPR 9 animals a larger increase in Bmax for both high and low affinity GABA sites, with no change in Kd. Chloride-dependent, barbiturate-enhanced GABA binding (increased Bmax) was observed in all conditions and groups. Likewise benzodiazepine binding (Bmax) increased slightly in GEPR 9 animals. There were no observed changes in binding sites for a survey of biogenic amines. Seizure-prone animals appear to have compensatory denervation-like supersensitivity for their most prominent inhibitory receptor, which may or may not be linked to the seizure event.     

The genetically epilepsy-prone rat: an overview of seizure-prone characteristics and responsiveness to anticonvulsant drugs

The Genetically Epilepsy-Prone Rat (GEPR) is rapidly gaining support as a model of epilepsy. In addition to a marked sensitivity to both sound-induced and hyperthermic seizures, GEPRs exhibit unusual sensitivity to a number of seizure-provoking modalities, including various forms of electrical and chemical stimulation. The existence of a moderate seizure colony (GEPR-3) and a severe seizure colony (GEPR-9) allows pathophysiological studies of seizure susceptibility and severity. The consistency of seizures within each colony allows for comparisons in seizure naive GEPRs and seizure experienced GEPRs. The consistent seizure responses of the GEPR are also ideal for the testing of anticonvulsant drugs. Further, the relative potencies of anticonvulsant drugs between the two colonies of GEPRs predict the clinical efficacies of traditional antiepileptic drugs and may be able to predict novel anticonvulsants.     

Brain norepinephrine and convulsions in the genetically epilepsy-prone rat: sex-dependent responses to Ro 4-1284 treatment

Seizure predisposition in the Genetically Epilepsy-Prone Rat (GEPR) is at least partially dependent on central nervous system noradrenergic deficits. We have previously shown that moderate seizure GEPRs (GEPR-3) experience an increase in seizure severity after receiving Ro 4-1284, a monoamine vesicle inactivating drug. We are now reporting the effect of this drug on severe seizure GEPRs (GEPR-9). Motives for this study were: (a) to determine the effects of further depletion of innately deficient monoaminergic stores on seizure latencies and (b) to investigate whether a previously documented seizure severity difference between the sexes is related to the defective monoaminergic system in these subjects. GEPR-9s with known seizure history were tested for latency to onset of running phase and convulsion 45 minutes after Ro 4-1284 or saline administration. Brain norepinephrine levels were also determined. Ro 4-1284 caused severe depletion of monoamines in all brain areas assayed in both sexes of GEPR-9s and also caused a reduction in the latencies for onset of running and convulsion. The drug-induced norepinephrine depletion across the brain areas surveyed was significantly greater in females than in their male littermates. These observations prompt us to postulate that noradrenergic neurons in female GEPR-9s are functionally different from those in males and that this difference is detected in the differential effectiveness of Ro 4-1284 between the two sexes. Also, the influence of gonadal hormones on seizure predisposition and on the neurochemical actions of Ro 4-1284 may be different in GEPR-9 males and females.     

Localization,metabolism, and binding of estrogens in the male rat

Estrogen assimilation by male Wistar rats was examined in these studies in several accessory sex organs (seminal vesicles and anterior, dorsal, lateral, and ventral prostates) as well as in a variety of nonaccessory sex organs. When [³H]estradiol was injected into intact 3- to 4-month-old rats in a pulse dose, no selective accumulation of radioactivity recovered as estradiol was found in the accessory sex glands when compared to other organs. This was due at least in part to the metabolism of estradiol to estrone and to the relatively low concentration of high affinity estrophilic molecules in the accessory sex organs. The order for the rate of formation of estrone from estradiol in tissues obtained from intact animals was ventral prostate > lateral and dorsal prostate > anterior prostate and seminal vesicles. Steroid specificity studies for cytosol estradiol binding by the ventral prostate and seminal vesicles revealed that estrophilic molecules exist in these organs. Based on Scatchard plot analyses in 24-h castrates, the number of available estradiol binding sites was too low in the ventral prostate to quantify accurately, but the seminal vesicles contained distinctly more estrophilic activity than the ventral prostate. The affinity for the seminal vesicle cytosol estradiol-estrophile binding exceeded that quantified for the seminal vesicle dihydrotestosterone-androphile reaction while the number of estradiol binding sites was less than that quantified for dihydrotestosterone. In relation to the accessory sex organs of other species, the rat seminal vesicles have a relatively small amount of cytosol estrophile. The findings that the seminal vesicles catabolize less estradiol and contain significantly more estrophilic activity than the ventral prostate is consistent with and offers insight into the noted estrogenic sensitivity of the seminal vesicles and lack thereof in the rat ventral prostate. With aging of the rat from 3–4 months to 22–26 months, the affinity of the seminal vesicle estradiol-estrophile interaction was unchanged but the number of binding sites increased significantly.     

Differential regulation of androgen receptors in the separate rat prostate lobes: androgen independent expression in the lateral lobe

In order to understand the hormonal regulation of androgen receptors (AR) in the separate lobes of the rat prostate gland, the present study examined AR levels in the ventral, dorsal and lateral prostate lobes as a function of androgen withdrawal to complete prostatic regression and subsequent testosterone replacement. In the intact rat, the 3 prostate lobes contained significantly different amounts of androgen binding sites. Mean number of total cellular AR in the ventral, dorsal and lateral lobes was 7370, 1690, and 1015 fm/mg DNA, respectively. These receptors were primarily localized within the nuclear fraction of homogenized tissue: ventral, 86%; dorsal, 83%; and lateral, 100% nuclear localization. Androgen withdrawal was initiated via castration and rats were sacrificed 1, 2, 3, 5, 7, 10 and 14 days thereafter. Nuclear AR levels fell rapidly to 5, 24 and 30% of intact values by 48 h in the ventral, dorsal and lateral lobes, respectively. Levels of nuclear AR continued to decline in the ventral and dorsal lobes to undetectable levels by Day 10. In marked contrast, lateral lobe nuclear AR began to increase on Day 3 postcastration, reaching intact values by Day 7 and 133% intact levels by Day 14. Cytosolic AR in the ventral and dorsal lobes initially increased following castration, but subsequently declined to low levels by Day 14. Cytosolic AR were not detectable in the lateral prostate at any time point following castration. To determine the nuclear AR response to testosterone at this time, 14 day castrate rats were given 2 cm testosterone implants and sacrificed 1, 3, 5, 7, 10 and 14 days thereafter. As expected, nuclear AR rapidly returned in the ventral and dorsal lobes by Day 1 and reached a plateau by Day 5. A short term response to androgen exposure occurred in the lateral lobe where an immediate 9-fold increase in nuclear AR quantity was observed; however, these levels rapidly declined to pre-implant values by Day 5 and remained at that level despite continued exposure to testosterone. These f findings indicate that while nuclear AR levels in the ventral and dorsal prostate are primarily regulated by androgens, a testosterone-independent component exists within the lateral lobe.     

Opioid-specific recognition sites of the mu- and the delta-type in rat striatum after lesions with kainic acid

The binding of 3H-dihydromorphine (3H-DHM) and of 3H-D-ala2, D-leu5-enkephalin (3H-DADL), which are regarded as relatively selective ligands for mu- or delta-type opioid receptors, respectively, was estimated in total particulate fraction of the striatum of rats in vitro, either in tissue of rats after striatal chemolesions with kainic acid or in control rats (not operated or saline injected into the striatum). Kainate lesions reduced the Bmax values of 3H-DHM by about 78 - 88% depending on the method of calculation, and of 3H-DADL by greater than 90%. Furthermore they lowered the Kd-values, suggesting an increase in affinity. The results are discussed with regard to recent hypotheses on the structure and function of opioid receptors.     

The influence of aging on androgen dynamics in the male rat

Androgen assimilation was investigated in a variety of accessory sex organs (seminal vesicles and anterior, dorsal, lateral, and ventral prostates) and in several nonaccessory sex organs in male Wistar rats. After administration of a pulse dose of [³H]testosterone in vivo to intact young (3–4 months old) rats, [³H]testosterone was the primary radioactive steroid recovered from most organs examined, except for the secondary sex glands where the reduced metabolites, [³H]5α-dihydrotestosterone (DHT) and [³H]5α-androstanediol(s), predominated. At longer postinjection times, [³H]DHT was preferentially retained in the accessory sex glands, presumably reflecting intracellular metabolism of [³H]testosterone to this compound and subsequent specific binding of [³H]DHT to receptor proteins. At the longest postinjection interval investigated, the ventral prostate retained greater concentrations of [³H]DHT than the lateral prostate which in turn had a higher [³H]DHT concentration than the seminal vesicles or anterior or dorsal prostates. The latter three glands retained approximately equal concentrations of [³H]DHT. Scatchard plot analyses of cytosol binding in 24-h castrates indicated that with one exception, the level of high affinity DHT binding sites was generally correlated with the retention of [³H]DHT in vivo in intact rats. Specifically, while the affinity for DHT binding in all accessory sex organs was the same, the number of high affinity binding sites per mg wet tissue weight was on the order of ventral prostate > anterior prostate ≥ seminal vesicles ≥ dorsal prostate > lateral prostate. Studies of the influence of aging to 22–26 months revealed no apparent differences in the affinity of the DHT receptor for its ligand in any of the accessory sex glands from 24-h castrates when the receptors were present in levels sufficiently high to quantify. The concentration of available DHT receptors with advancing age remained constant in the anterior and dorsal prostates, increased in the seminal vesicles, and declined in the ventral and lateral prostates. The decreases observed in the ventral prostate were only partial, but the receptors of the lateral prostate declined to nondetectable levels.     

Role of glutathione peroxidase in the ontogeny of hippocampal oxidative stress and kainate seizure sensitivity in the genetically epilepsy-prone rats

Oxidative stress may contribute to epileptogenicity in genetic models of epilepsy. To address this, we examined the enzymatic activity of cytosolic Cu/Zn superoxide dismutase (SOD-1), mitochondrial Mn superoxide dismutase (SOD-2), and glutathione peroxidase (GPx) in the developing hippocampus of genetically epilepsy-prone rats (GEPR-9s). We also measured changes in the GSH/GSSG ratio, lipid peroxidation, and protein oxidation at post-natal days (PD) 7, 30, and 90, respectively. Compared with control Sprague-Dawley (SD) rats, GEPR-9s showed similar SOD-1 and SOD-2 activity but lower GPx activity. Epilepsy-prone rats also showed lower GSH/GSSG ratios than controls, and more lipid peroxidation (as measured by malondialdehyde levels) and protein oxidation (as measured by carbonyl levels). Treatment with kainic acid (KA) resulted in more pronounced seizures, less GPx activity, and lower GSH/GSSG ratios in GEPR-9s than in controls, but KA did not significantly affect SOD-1 or SOD-2 activity, suggesting that GEPR-9s do not compensate for reduced GPx activity by increasing SOD. Moreover, KA treatment resulted in significantly a lower GSH/GSSG ratio and GPx-like immunoreactivity and higher malondialdehyde and carbonyl levels in GEPR-9s than in controls. These findings were more evident in GEPR-9s at PD 90 than at PD 30, indicating that oxidative stress is age-dependent. Double-labeling immunocytochemical analysis demonstrated co-localization of GPx-immunoreactive glia-like cells and reactive astrocytes, as labeled by glial fibrillary acidic protein (GFAP). This suggests that mobilization of astroglial cells for synthesis of GPx protein is a response to KA insult, intended to decrease the neurotoxicity induced by peroxides. These responses were more pronounced in control SD rats than in GEPR-9s. Our results suggest that impairment of the GPx (including glutathione)-mediated antioxidant system contributed to epileptogenesis in GEPR-9s.     

Sleep, temperature, activity, and prolactin phenotypes of genetically epilepsy-prone rats

Sleep-wake disturbances are common in epilepsy, yet the potential adverse effect of seizures on sleep is not well characterized. Genetically epilepsy-prone rats (GEPRs) are a well-studied model of genetic susceptibility to audiogenic seizures. To assess their suitability for investigating relationships between seizures and disordered sleep, we characterized the sleep, activity, and tempera ture patterns of 2 GEPR strains (designated 3 and 9) and Sprague-Dawley (SD) rats in the basal state, after forced wakefulness, and after exposure to sound-induced seizures at light onset and dark onset. Because of observed differences in rapid-eye-movement sleep (REMS), we also assessed serum levels of prolactin, which is implicated in REMS regulation. The data reveal that under basal conditions, the GEPR3 strain shows less SWS and REMS, higher core temperatures, and higher serum prolactin concentrations than do GEPR9 and SD strains. All 3 strains respond similarly to enforced sleep loss. Seizures induced at light onset delay the onset of SWS in both GEPR strains. Seizures induced at dark onset do not significantly alter sleep. Genotype assessment indicates that although both GEPR strains are inbred (that is, homozygous at 107 genetic markers), they differ from each other at 74 of 107 loci. Differences in basal sleep, temperature, and prolactin between GEPR3 and GEPR9 strains suggest different homeostatic regulation of these functions. Our detection of concurrent alterations in sleep, temperature, and prolactin in these 2 GEPR strains implicates the hypothalamus as a likely site for anatomic or physiologic variation in the control of these homeostatic processes.     

Abnormality of α1Adrenergic Receptors in the Frontal Cortex of Epileptic Rats

Abstract: We found that the binding of [³H]prazosin, a selective ligand for α₁-adrenergic recognition sites, is significantly lower in the frontal cortex of the genetically epilepsy-prone rats (GEPRs), as compared with normal Sprague-Dawley rats. Scatchard analysis reveals a decrease in the B _max of [³H]prazosin binding with no change in the apparent K _D, suggesting that there are fewer α₁-adrenergic recognition sites in the frontal cortex of the GEPR. This abnormality is associated with a reduced capacity of norepinephrine (NE) to stimulate [³H]inositol monophosphate ([³H]IP₁) formation in frontal cortex slices prelabeled with [³H]inositol. No significant differences in [³H]prazosin binding as well as NE-stimulated [³H]IP₁ formation have been observed in other brain regions including hippocampus, corpus striatum, and inferior colliculus. These results indicate that a deficit in the α₁-adrenergic receptor system in the frontal cortex may play a role in the seizure process in the GEPR.     

Expression of serotonin transporter in the dorsal raphe nucleus during the early postnatal period in the normal state and under prenatal deficiency of the serotonergic system in rats

Expression of the serotonin transporter protein (5-NTT) in the dorsal raphe nucleus (DNR) during the early postnatal period was investigated in laboratory Wistar rats. Immunocytochemical labeling showed that during the first 3 postnatal weeks the intensity of 5-NTT expression in DNR of control animals changes. During the earliest postnatal stages, most of DNR subnuclear neurons (dorsal, DNR-d; ventral, DNR-v; lateral, DNR-lat) were found to intensely express 5-NTT. 5-NTT localization sites were revealed on the membrane surface of neuronal cell bodies and their processes in neuropil. On P10, the number of 5-NTT expressing neurons and 5-NTT binding sites decreases. At this time, the 5-NTT binding sites were shown to undergo redistribution becoming very few on neuronal cell bodies and dendrites, but rather densely packed in the axonal membrane. The number of 5-NTT expressing neurons and density of 5-NTT localization sites in neuropil gradually increases with age. The reduction in the serotonin level in all DNR regions during prenatal development leads to the reduction both in the number of 5-NTT expressing neurons and 5-NTT localization sites during the early postnatal period. This tendency was shown to persist with age.     

Clinical patent ductus arteriosus in adult genetically epilepsy-prone rats

Persistent patent ductus arteriosus (PDA) and clinically silent PDAs are relatively common congenital cardiac defects in humans. We report here the occurrence of symptomatic PDA in adults from a colony of genetically epilepsy-prone rats (GEPRs). Affected rats displayed severe ventral edema. Echocardiography revealed PDA in several animals. Necropsy findings included cardiomegaly, hepatic hyperemia and centrilobular necrosis indicative of passive congestion, and vascular changes consistent with pulmonary hypertension. All affected rats were descendants of one of two brother-sister breeding pairs established from a single litter in April 2000. Clinically silent PDAs were also detected in the colony. Histological examination of the ligamentum arteriosus showed normal vascular tissue in asymptomatic GEPR and Sprague-Dawley rats. PDAs are likely to have a genetic component in the GEPR colony and may provide a novel model for the study of pathogenesis and therapy of this condition.     

Hippocampal 8-[3H]Hydroxy-2-(Di-n-Propylamino)Tetralin Binding Site Densities, Serotonin Receptor (5-HT1A) Messenger Ribonucleic Acid Abundance, and Serotonin Levels Parallel the Activity of the Hypothalamopituitary-Adrenal Axis in Rat

We have previously demonstrated that susceptibility of the Lewis rat to inflammatory disease, compared with the relatively resistant Fischer F344/N rat, is related to a hyporesponsive hypothalamopituitary-adrenal axis to inflammatory and other stress mediators. Because serotonin (5-HT) and the 5-HT1A receptor are important stimulators of this axis, we have investigated the levels of 8-[3H]-hydroxy-2,3-(di-n-propylamino)tetralin binding sites, 5-HT1A mRNA, 5-HT, and 5-hydroxyindoleacetic acid in various brain regions of Lewis, outbred Harlan Sprague Dawley, and Fischer F344/N rats. Lewis rats expressed significantly fewer hippocampal and frontal cortical 8-[3H]-hydroxy-2,3-(di-n-propylamino)tetralin binding sites and less 5-HT1A mRNA than Harlan Sprague Dawley and Fischer F344/N rats. Adrenalectomy increased the number of 8-[3H]hydroxy-2,3-(di-n-propylamino)tetralin binding sites and 5-HT1A mRNA expression in the hippocampus of all three strains. Levels of hippocampal 5-HT in Fischer F344/N rats were significantly greater than levels detected in the same regions from Lewis and Harlan Sprague Dawley rats. Hypothalamic 5-HT and 5-hydroxyindoleacetic acid levels in Harlan Sprague Dawley rats were higher than the same area from the other two strains. Adrenalectomy increased the levels of 5-hydroxyindoleacetic acid in the hypothalamus of all three strains. We conclude that hippocampal 5-HT1A receptor densities and 5-HT levels in the rat parallel the activity and responsiveness of the hypothalamopituitary-adrenal axis.     

Modulation of [3H]Paroxetine Binding to the 5-Hydroxytryptamine Uptake Site in an Animal Model of Depression

The effects of learned helplessness on the 5-hydroxytryptamine (5-HT) uptake site were studied in rats using [3H]paroxetine binding. This ligand was chosen because it was demonstrated to label directly the 5-HT uptake site whereas the [3H]imipramine binding site has been demonstrated to be heterogeneous in nature. Moreover, [3H]imipramine appears to bind to a presynaptic recognition site different from the uptake site. Exposure to uncontrollable shock training and testing resulted in an overall increase in [3H]paroxetine binding in all the groups studied [nonhelpless (NLH), learned helpless (LH), spontaneously helpless (SPLH)] as compared to naive controls (NC). However, the increase in [3H]paroxetine binding was significantly higher in the LH and SPLH groups. The maximum number of [3H]paroxetine binding sites in the rat hippocampus was increased significantly in learned helpless rats (LH and SPLH) at day 4 and day 30 after the shock escape test as compared to NC and NLH rats. By contrast, in the rat hypothalamus the maximum number of [3H]paroxetine binding sites was reduced significantly in the LH rats as compared to naive controls and NLH rats during the same time course. There was no change in [3H]paroxetine binding sites in any other brain regions examined in LH, NLH, and NC rats. The results suggest that a hippocampal hypothalamic connection might play a role in the serotonergic mediation of learned helpless behavior.