Corticotropin releasing hormone related behavioral and neuroendocrine responses to stress in Lewis and Fischer rats

We have recently shown that susceptibility to streptococcal cell wall (SCW)-induced arthritis in Lewis (LEW/N) rats is related to a lack of glucocorticoid restraint of inflammation while the relative SCW arthritis resistance in histocompatible Fischer (F344/N) rats is related to their greater hypothalamic-pituitary-adrenal (HPA) exis response. The difference in pituitary-adrenal responsiveness results from decreased inflammatory mediator-induced hypothalamic corticotropin-releasing hormone (CRH) biosynthesis and secretion in LEW/N rats. Because CRH not only activates the pituitary-adrenal axis, but also is associated with behavioral responses that are adaptive during stressful situations, we wished to determine if the differential LEW/N and F344/N CRH responsiveness to inflammatory mediators could also be associated with differences in neuroendocrine and behavioral responses to physical and emotional stressors. In this study, LEW/N rats exhibited significant differences compared to F344/N rats, in plasma adrenocorticotropin hormone (ACTH) and corticosterone responses during exposure to an open field, swim stress, restraint or ether. Furthermore, hypothalamic paraventricular CRH mRNA expression was also significantly lower in LEW/N compared to F344/N rats after restraint. These differences in neuroendocrine responses were associated with differences in behavioral responses in LEW/N compared to F344/N rats in the open field. Outbred HSD rats, which have intermediate and overlapping arthritis susceptibility compared to LEW/N and F344/N rats, exhibited intermediate and overlapping plasma corticosterone and behavioral responses to stressful stimuli compared to the two inbred strains. These data suggest that the differences in CRH responses in these strains may contribute to the behavioral and neuroendocrine differences we have observed. Therefore these strains may provide a useful animal model for studying the relationship between behavior, neuroendocrine and inflammatory responses.     

Genetic differences in NMDA and D1 receptor levels,and operant responding for food and morphine in Lewis and Fischer 344 rats

Previously, we have shown that Lewis (LEW) rats acquire faster than Fischer 344 (F344) rats operant food- and morphine-reinforced tasks under fixed-ratio schedules of reinforcement. The first purpose of the present work has been to study if differences in operant responding behavior may participate in the reported differences in morphine self-administration behavior between both inbred rat strains. To this end, we have analyzed the microstructure of responding obtained under a variable-interval (VI) of food reinforcement by calculating the inter-response time (IRT) for each rat strain. LEW rats exhibited shorter IRTs than F344 rats, suggesting that LEW rats may have an inherent high or compulsive operant responding activity. When subjects of both inbred rat strains were submitted to a schedule of morphine reinforcement of high responding requirements such as progressive ratio schedules, LEW rats also reached significantly higher breaking points and final response ratio than F344 rats for i.v. morphine self-administration. Given that there are neurochemical differences between both rat strains and that glutamatergic N-methyl-D-aspartate (NMDA) and dopaminergic D(1) receptors have been involved in operant responding behavior, a second purpose of this work has been to measure basal NMDA and D(1) receptor levels in these rat strains by quantitative receptor autoradiography. Compared to F344 rats, LEW rats showed higher basal NMDA receptor levels in frontal and cingulate cortex, caudate putamen, central amygdaloid nuclei, and intermediate white layer of superior colliculus, and higher basal D(1) receptor levels in several areas of hippocampus and thalamus, and substantia nigra pars reticulata. Taken together, these results suggest that an inherent high operant responding activity of LEW rats may have a role in the previous reported faster acquisition of opiate-reinforced behavior in operant self-administration paradigms under fixed-ratio schedules of reinforcement. In addition, a basal higher NMDA and D(1) receptor levels of LEW rats compared to F344 rats may participate in the neurochemical background that mediates the behavioral differences between both inbred rat strains.     

The febrile response to intraperitoneal lipopolysaccharide: strain and gender differences in rats

The acute-phase febrile responses of the inbred Lewis (LEW) and Fischer 344 (F344) rat strains and their parent Sprague-Dawley (S-D) strain to immune challenge with lipopolysaccharide (LPS) were compared. LEW and S-D males and females displayed a biphasic febrile response with a markedly attenuated second phase in F344 rats. At 2 h after LPS (50 microg/kg), corticosterone was significantly higher in F344 than in LEW rats, but serum interleukin-1beta was higher only in F344 than LEW males. These data suggest that the greater LPS-induced corticosterone response of F344 rats mediates differences between febrile responses of F344 and LEW males and females.     

Genetic differences in NMDA and D1 receptor levels, and operant responding for food and morphine in Lewis and Fischer 344 rats

Previously, we have shown that Lewis (LEW) rats acquire faster than Fischer 344 (F344) rats operant food- and morphine-reinforced tasks under fixed-ratio schedules of reinforcement. The first purpose of the present work has been to study if differences in operant responding behavior may participate in the reported differences in morphine self-administration behavior between both inbred rat strains. To this end, we have analyzed the microstructure of responding obtained under a variable-interval (VI) of food reinforcement by calculating the inter-response time (IRT) for each rat strain. LEW rats exhibited shorter IRTs than F344 rats, suggesting that LEW rats may have an inherent high or compulsive operant responding activity. When subjects of both inbred rat strains were submitted to a schedule of morphine reinforcement of high responding requirements such as progressive ratio schedules, LEW rats also reached significantly higher breaking points and final response ratio than F344 rats for i.v. morphine self-administration. Given that there are neurochemical differences between both rat strains and that glutamatergic N-methyl- -aspartate (NMDA) and dopaminergic D₁ receptors have been involved in operant responding behavior, a second purpose of this work has been to measure basal NMDA and D₁ receptor levels in these rat strains by quantitative receptor autoradiography. Compared to F344 rats, LEW rats showed higher basal NMDA receptor levels in frontal and cingulate cortex, caudate putamen, central amygdaloid nuclei, and intermediate white layer of superior colliculus, and higher basal D₁ receptor levels in several areas of hippocampus and thalamus, and substantia nigra pars reticulata. Taken together, these results suggest that an inherent high operant responding activity of LEW rats may have a role in the previous reported faster acquisition of opiate-reinforced behavior in operant self-administration paradigms under fixed-ratio schedules of reinforcement. In addition, a basal higher NMDA and D₁ receptor levels of LEW rats compared to F344 rats may participate in the neurochemical background that mediates the behavioral differences between both inbred rat strains.     

Differential basal proenkephalin gene expression in dorsal striatum and nucleus accumbens, and vulnerability to morphine self-administration in Fischer 344 and Lewis rats

We have previously shown that the acquisition rate of intravenous morphine self-administration under a fixed ratio one (FR1) schedule of reinforcement was greater in Lewis (LEW) than Fischer 344 (F344) rats. The purpose of the present experiment was to examine the relative motivational properties of morphine (1 mg/kg) or food under progressive ratio (PR) schedules of reinforcement in LEW and F344 rats. In addition, by using in situ hybridization histochemistry we have measured in both strains of rats the basal level of proenkephalin (PENK) gene expression in dorsal striatum and nucleus accumbens (NAcc). The results show that LEW rats responded to significantly higher breaking points (BPs) than F344 rats for intravenous morphine self-administration. In contrast, no differences were found in BPs for food pellets. Basal PENK mRNA levels were significantly higher in the dorsal striatum and nucleus accumbens of F344 than in LEW rats. Taken together, these results reveal a strain difference in the reinforcing efficacy of morphine and in the basal PENK gene expression in brain regions involved in the reinforcing actions of opiates. These data also suggest that the strain differences in opiate self-administration behavior found in this and other studies may be related, at least in part, to differences in basal opioid activity between LEW and F344 rats.     

The effects of light cycle phase on morphine-induced conditioned taste aversions in the Lewis, Fischer and Sprague-Dawley rat strains

The present experiment investigated the effect of light cycle phase on morphine-induced conditioned taste aversions in the Lewis (LEW), Fischer (F344) and Sprague-Dawley (SD) rat strains. Separate groups of rats from each strain were trained during either the light phase or the dark phase on a procedure in which saccharin was paired with one of two doses of morphine (or vehicle). With 3.2mg/kg morphine, strain differences were observed during the light phase, with F344 rats displaying a significantly stronger taste aversion than the LEW rats, who displayed a significantly stronger aversion than the SD rats. In contrast, during the dark phase, 3.2mg/kg morphine produced comparable, moderately strong aversions in all strains. With 10.0mg/kg morphine, F344 rats developed stronger aversions than either the LEW or SD rats in both phases of the light cycle. The effect of light cycle was most clearly seen in the SD rats, where stronger aversions were produced in the dark phase for both morphine doses. For the LEW rats, stronger aversions were produced in the dark as compared to the light only with the low dose of morphine. For the F344 rats, aversions of comparable strength were observed in both phases of the light cycle for both morphine doses. The finding that light cycle differentially affects morphine-induced taste aversions in these strains is consistent with what is known about strain differences in circadian patterns of corticosterone activity and with previous results relating corticosterone to morphine-induced taste aversions.     

Differential activation of adrenal steroid receptors in neural and immune tissues of Sprague Dawley, Fischer 344, and Lewis rats

Sprague Dawley (SD), Fischer 344 (F344), and Lewis (LEW) rats are used in a wide variety of laboratory studies. Compared to SD and LEW rats, F344 rats show significantly greater corticosterone secretion in response to stress, or to immune challenge. These strain differences in hypothalamic-pituitary-adrenal (HPA) axis responsivity have been the basis for many comparative studies investigating immunological and behavioural differences between the three strains. However, the effects of these strain differences in HPA axis responsivity have not been investigated at the level of adrenal steroid receptor activation in target tissues. The present study demonstrates that compared to SD and LEW rats, F344 rats exhibited a greater magnitude of Type II adrenal steroid receptor activation in brain tissues during stress. In contrast, Type II receptor activation in immune tissues of F344 rats following stress was similar to that of SD rats. Importantly, LEW rats exhibited the lowest magnitude of activation of Type II receptors in immune tissues during stress. No differences were observed between strains in the extent of stress-induced Type I adrenal steroid receptor activation. The observed differences between strains in corticosteroid-binding globulin (CBG) levels in plasma, pituitary, and immune tissue may mediate the differential access of corticosterone to neural versus immune tissues. These results indicate that strain differences in corticosterone secretion are manifested by differences in Type II receptor activation in neural as well as immune tissues. Moreover, they suggest that increased access of corticosterone to adrenal steroid receptors in brain areas of F344 rats may contribute to behavioural differences between strains, whereas decreased access of hormone to receptors in immune tissues of LEW rats may contribute to strain differences in susceptibility to autoimmune disease.     

Increased hypothalamic [3H]flunitrazepam binding in hypothalamic-pituitary-adrenal axis hyporesponsive Lewis rats.

We have previously demonstrated that susceptibility of Lewis (LEW/N) rats to inflammatory disease, compared to relatively resistant Fischer (F344/N) rats, is related to deficient glucocorticoid counter-regulation of the immune response resulting from deficient corticotropin-releasing hormone (CRH) responsiveness to inflammatory and other stress mediators. The GABA/benzodiazepine receptor complex is an important negative modulator of CRH secretion and responsiveness to excitatory stimuli. In this study, we have examined in vitro binding of [3H]flunitrazepam to hypothalamic membrane preparations from LEW/N and F344/N rats. LEW/N rats had significantly more hypothalamic benzodiazepine binding sites (Bmax) than F344/N rats, but there were no differences in benzodiazepine binding affinities (Kd) between these two strains. The differences in benzodiazepine receptor number were consistent with the respective plasma corticosterone levels in the two strains, and with previous work indicating a negative correlation between corticosterone levels and benzodiazepine binding site number. Adrenalectomy of F344/N rats increased benzodiazepine binding to levels comparable to LEW/N animals and treatment of adrenalectomized F344/N rats with DEX resulted in lowering of benzodiazepine Bmax to levels that did not differ significantly from those of intact F344/N rats. There was no significant change in receptor number in either adrenalectomized or DEX-treated LEW/N rats. These findings suggest that basal benzodiazepine receptor differences between these strains may be partially related to strain differences in corticosterone levels, however that additional factors may contribute to maintenance of these differences in LEW/N rats. Since benzodiazepines attenuate hypothalamic CRH secretion through GABAergic inhibition, we suggest that strain differences in receptor number could also augment strain differences in hypothalamic-pituitary-adrenal axis function through differential sensitivity to GABA-mediated feedback.     

Comparison of the behavioural and endocrine response to forced swimming stress in five inbred strains of rats

Some inbred strains of rats showed behavioural differences in the forced swimming test, which is considered a putative animal model of depression. In the present work, the behavioural and physiological responses to forced swimming were studied in male and female rats of five inbred strains of rats: Brown-Norway (BN), Fischer 344 (FIS), Lewis (LEW), Spontaneously Hypertensive (SHR) and Wistar-Kyoto (WKY). Physiological measures were aimed at characterizing emotional reactivity, a very important issue which has usually been approached by studying a single endocrine system, and its relationship to the forced swimming behaviour. The four indices of reactivity to stress used were serum glucose, ACTH, corticosterone and prolactin. No behavioural differences between sexes were observed in the forced swimming test. In addition, BN and WKY rats showed passive behaviour compared with the other three strains, the FIS strain being the most active. Whereas only minor differences were found in the resting levels of the variables studied with regard to either sex or strain, pituitary-adrenal (PA) and glucose responses to 15 min forced swimming differed among sexes and strains. Stress-induced hyperglycaemia was lowest in WKY and highest in SHR, being lower in females than in males. The lowest ACTH and corticosterone responses to forced swimming were observed in LEW and the highest in FIS. Female rats showed a clearly higher PA response to stress in all strains. Prolactin response to stress was very similar between sexes and strains. It might thus be concluded that: (i) there are important inter-strain differences in the forced swimming behaviour, with no differences between sexes; (ii) the various physiological indices of emotional reactivity follow a different trend and no warranted conclusion on differences in emotional reactivity should be based upon a single endocrine system or even only upon physiological measures; (iii) we cannot be sure, therefore, whether or not there are differences in emotionality between the strains studied in spite of well-established inter-strains differences in the forced swimming behaviour.     

Morphine- and cocaine-induced c-Fos levels in Lewis and Fischer rat strains

Lewis (LEW) and Fischer 344 (F344) rat strains have been reported to differ in their sensitivity to the rewarding and aversive effects of both cocaine and morphine. Specifically, LEW rats self-administer morphine and cocaine to a greater extent than F344 rats, while LEW (compared to F344) rats are more sensitive to the aversive effects of cocaine but less sensitive to the aversive effects of morphine. Consistent with assessments of the rewarding effects of morphine and cocaine in these two strains, LEW rats have lower basal, and generally higher drug-induced, activity in brain regions associated with reward. Although the brain areas that mediate the aversive effects of drugs are becoming better defined, no studies have compared the activation of these areas by aversion-inducing drugs in the LEW and F344 strains. As such, the relationship between the ability of drugs to activate these aversion-associated brain areas and to induce a conditioned taste aversion (CTA) in these strains is unknown. To explore this relationship, LEW and F344 rats were injected with saline or doses of morphine or cocaine (32 mg/kg for both drugs) that have been shown to generate differential taste aversion learning in these strains. All animals were subsequently tested for c-Fos expression in areas of the brain associated with aversion learning (the lateral and medial parabrachial nucleus, intermediate and caudal nucleus tractus solitarius and area postrema), reward (the shell of the nucleus accumbens) and locomotion (the core of the nucleus accumbens and the caudate putamen). The present results indicated that patterns of morphine- and cocaine-induced c-Fos within CTA-associated, but not reward- or locomotor-associated, brain regions paralleled the differential behavioral sensitivities of LEW and F344 rats to these drugs within CTA learning. Analyses with other drugs that do and do not induce aversions differentially would further assess the role of these brain areas in aversion learning, in general, and in strain-dependent differences, in particular.     

Increased hypothalamic [H]flunitrazepam binding in hypothalamic-pituitary-adrenal axis hyporesponsive Lewis rats

We have previously demonstrated that susceptibility of Lewis (LEW/N) rats to inflammatory disease, compared to relatively resistant Fischer (F344/N) rats, is related to deficient glucocorticoid counter-regulation of the immune response resulting from deficient corticotropin-releasing hormone (CRH) responsiveness to inflammatory and other stress mediators. The GABA/benzodiazepine receptor complex is an important negative modulator of CRH secretion and responsiveness to excitatory stimuli. In this study, we have examined in vitro binding of [³H]flunitrazepam to hypothalamic membrane preparations from LEW/N and F344/N rats. LEW/N rats had significantly more hypothalamic benzodiazepine binding sites (B_max) than F344/N rats, but there were no differences in benzodiazepine binding affinities (K_d) between these two strains. The differences in benzodiazepine receptor number were consistent with the respective plasma corticosterone levels in the two strains, and with previous work indicating a negative correlation between corticosterone levels and benzodiazepine binding site number. Adrenalectomy of F344/N rats increased benzodiazepine binding to levels comparable to LEW/N animals and treatment of adrenalectomized F344/N rats with DEX resulted in lowering of benzodiazepine B_max to levels that did not differ significantly from those of intact F344/N rats. There was no significant change in receptor number in either adrenalectomized or DEX-treated LEW/N rats. These findings suggest that basal benzodiazepine receptor differences between these strains may be partially related to strain differences in corticosterone levels, however that additional factors may contribute to maintenance of these differences in LEW/N rats. Since benzodiazepines attenuate hypothalamic CRH secretion through GABAergic inhibition, we suggest that strain differences in receptor number could also augment strain differences in hypothalamic-pituitary-adrenal axis function through differential sensitivity to GABA-mediated feedback.     

Fischer and Lewis rat strains differ in basal levels of neurofilament proteins and their regulation by chronic morphine in the mesolimbic dopamine system.

We studied levels of neurofilament (NF) proteins in the ventral tegmental area (VTA), and other regions of the central nervous system, of two genetically inbred rat strains, Lewis (LEW) and Fischer (F344) rats. These strains represent genetically divergent populations of rats that have been used to study possible genetic factors involved in a variety of biological processes, including drug addiction: compared to F344 rats, LEW rats show a much higher preference for several classes of drugs of abuse. We found 30-50% lower levels of three NF proteins, NF-200 (NF-H), NF-160 (NF-M), and NF-68 (NF-L), in the VTA of LEW compared to F344 rats by use of immunolabeling and Coomassie blue staining. These strain differences were highly specific to this brain region, with no differences observed elsewhere in brain or spinal cord. Interestingly, chronic treatment of F344 rats with morphine decreased levels of these three NF proteins in the VTA, as found previously in outbred Sprague-Dawley rats (Beitner-Johnson, D., Guitart, X., and Nestler, E.J.:J. Neurosci., 12:2165-2176, 1992), whereas morphine had no effect on NF levels in the VTA of LEW rats. A similar strain difference was observed in chronic morphine regulation of tyrosine hydroxylase, with morphine increasing enzyme immunoreactivity in the VTA of F344 rats (as has been observed previously in Sprague-Dawley rats [Beitner-Johnson, D., and Nestler, E.J.:J. Neurochem., 57:344-347, 1991]), but not in LEW rats. In view of the observations that LEW and F344 rats show different levels of preference for several types of drugs of abuse, and of the evidence supporting a central role of the mesolimbic dopamine system in drug reward mechanisms, the results of the current study suggest the possibility that levels of NFs and tyrosine hydroxylase may mediate some aspects of drug reinforcement and contribute to individual genetic differences in vulnerability to drug addiction.     

EEG, EEG power spectral, and behavioral differences in response to acute ethylketocyclazocine administration in two inbred rat strains

Differences in response to behavioral and electroencephalographic parameters were delineated between two inbred rat strains, Lewis (LEW) and Fischer 344 (F344), upon acute exposure to IV administration of ethylketocyclazocine (EKC) at doses of 1.25 2.5, and 5 mg/kg. Duration of EKC-induced EEG slow-wave bursts and associated behavioral stupor increased in a dose-related manner, and was greater in duration for the LEW animals; a less robust, quadratic trend was displayed by the F344 group. For both rat strains, latency to onset of slow-wave sleep increased proportionately with EKC dose. Duration of EKC-induced EEG bursts and interbursts were greater in duration for the F344 rats. Assessment of six power spectral parameters (peak frequency, complexity, mobility, mean frequency, edge frequency, and total power) revealed no differences between groups when EKC-induced burst and interburst periods were analyzed simultaneously. Separation of the phases revealed rat strain differences; overall, the LEW animals displayed a greater dose-related EEG response. Except for total power, the F344 group displayed little variation across the three doses tested in the burst phase; the interburst phase reflected more dose-related differences for this group but to a lesser degree than the LEW animals. These results may reflect differences in opioid-related receptor populations between Lewis and F344 inbred rat strains.     

Arthritis-susceptible Lewis rats fail to emerge from the stress hyporesponsive period.

Susceptibility to streptococcal cell wall (SCW)-induced arthritis in 4- to 6-week-old Lewis (LEW/N) rats is associated with blunted glucocorticoid production secondary to a profound defect in inflammatory mediator-induced hypothalamic corticotropin-releasing hormone (CRH) biosynthesis and secretion. The relative SCW arthritis resistance in histocompatible Fischer (F344/N) rats, on the other hand, is associated with robust hypothalamic-pituitary-adrenal (HPA) axis responses to inflammatory mediators. In this study, we investigated HPA axis responses to SCW during the postnatal developmental period in LEW/N and F344/N rats. We found that SCW-induced plasma corticosterone (CORT) responses do not significantly increase during development in LEW/N, while such responses clearly appear at postnatal day 14 in F344/N and outbred Harlan-Sprague-Dawley (HSD) rats. Additionally, LEW/N rats fail to exhibit the normal ontogenic increase in CRH mRNA levels in the paraventricular nucleus (PVN), whereas their SCW-induced PVN CRH mRNA responses are blunted compared to F344/N at postnatal day 14. Taken together, these results suggest that LEW/N rats fail to emerge completely from their stress hyporesponsive period. This may account for the lack of stress responsiveness in young adult LEW/N rats, and consequently, for their susceptibility to SCW-induced arthritis and other inflammatory diseases.     

Differential behavioral responses to cocaine are associated with dynamics of mesolimbic dopamine proteins in Lewis and Fischer 344 rats

Differential behavioral and biochemical responses to drugs of abuse may reflect genetic makeup as suggested by studies of inbred Lewis (LEW) and Fischer 344 (F344) rats. We investigated locomotor activity, stereotypy signs, and levels of specific proteins in the nucleus accumbens (NAc) and ventral tegmental area (VTA) in these strains at baseline and following chronic administration of cocaine (30 mg/kg/day for 14 days). Using Western blot analysis, we replicated our previous findings of baseline strain differences and found lower levels of DeltaFosB immunoreactivity in NAc of F344 vs. LEW rats. F344 rats showed greater baseline locomotor activity, sniffing, and grooming compared to LEW rats. Chronic cocaine increased DeltaFosB levels in NAc in both strains, whereas adaptations in other proteins were induced in F344 rats only. These included reduced levels of tyrosine hydroxylase (TH) in NAc and increased TH and glial fibrillary acidic protein (GFAP) immunoreactivity in VTA. Chronic cocaine led to greater increases in overall stereotypy in F344 vs. LEW rats and decreased exploratory behaviors in LEW rats. Opposing effects by strain were seen in locomotor activity. Whereas F344 rats showed higher initial activity levels that decreased with cocaine exposure (tolerance), LEW rats showed increased activity over days (sensitization) with no strain differences seen at 14 days. Further, conditioned locomotor activation to vehicle injections was greater in F344 vs. LEW rats. These results suggest that behavioral responsiveness to chronic cocaine exposure may reflect dynamics of mesolimbic dopamine protein levels and demonstrate the role of genetic background in responsiveness to cocaine.     

HPA axis function and drug addictive behaviors: insights from studies with Lewis and Fischer 344 inbred rats.

Much research supports a link between stress and its concomitant hypothalamic-pituitary-adrenal (HPA) axis responses with behavioral sensitivity to psychoactive drugs. Our research demonstrates that Lewis inbred rats more readily acquire drug self-administration than Fischer 344 (F344) inbred rats and, compared to this strain, Lewis rats have hyporesponsive HPA axis responses to stress exposure. This association appears to conflict with investigations using outbred rats and suggests that the relationship between drug sensitivity and HPA axis responsiveness is more complicated than originally thought. It is essential to better understand this relationship because of its relevance to vulnerability and relapse to drug abuse. Thus, this paper reviews the literature in which these two inbred strains have been compared. We discuss strain differences in HPA axis function, in characteristics of the mesolimbic dopamine system, and in behaviors thought to reflect emotionality. Strain differences in unconditioned and conditioned effects of psychoactive drugs are then reviewed. Next, we discuss the possible role of sex and gonadal hormones on responsiveness to psychoactive drugs in these strains. Finally, a comparison of results obtained from these strains to three other comparator groups (e.g., high and low responders) suggests that a non-monotonic relationship between behavioral sensitivity to drugs and HPA axis responsiveness can explain much of the discrepancies in the literature.     

Genetic strain differences in platelet aggregation and thrombus formation of laboratory rats

Rats are employed to investigate the role of platelets in thrombus formation under flow conditions in vivo and to evaluate the pre-clinical potential of antiplatelet drugs. While Wistar and Sprague-Dawley (SD) strains are commonly used in thrombosis models, a number of rat strains have been established. Each strain possesses genetically unique characteristics such as hypertension, hyperglycemia or hyperlipidemia. The appropriate selection of a strain might have advantages for physiological and pharmacological studies. Comparative investigation of platelet aggregation among laboratory strains of rats is useful for the development of thrombosis models. In the present study, platelet aggregation response in eight laboratory rat strains, ACI, Brown Norway (BN), Donryu, Fischer 344 (F344), LEW, SD, Wistar and WKAH, were compared. Considerable strain differences were observed in ADP-, collagen- and TRAP-induced platelet aggregation. SD and BN are high-platelet-aggregation strains, while F344 and ACI are low-response strains. In the arteriovenous shunt thrombosis model, SD formed larger thrombi than F344 and Wistar rats. In the FeCl(3)-induced thrombosis model with the carotid artery, the time to occlusion of SD was significantly shorter than of F344 and ACI rats. F344 and ACI rats had significantly increased bleeding times compared with SD rat. The present study demonstrates that there are considerable strain differences in platelet aggregation among laboratory rats, which reflect thrombus formation.     

Strain differences in anxiety-like behavior: association with corticotropin-releasing factor

The purpose of the current study was to relate basal corticotropin-releasing factor (CRF) mRNA level in the central nucleus of the amygdala (CeA) with anxiety-like behavior using three strains of rat reported to exhibit a range of behavioral and neuroendocrine responses to stress. Anxiety-like behavior was determined for Fischer (F344), Wistar, and Wistar-Kyoto (WKY) rats with an elevated plus-maze and CRF mRNA level was measured using in situ hybridization. WKY rats exhibited more anxiety-like behavior on the elevated plus-maze than both F344 (p's < 0.01) and Wistar rats (p's < 0.05). WKY rats had higher basal levels of CRF mRNA in the CeA than F344 rats (p < 0.05) with a trend toward higher levels than Wistar rats (p = 0.06). Wistar rats had similar indices of anxiety with F344 rats and comparable levels of CRF mRNA in the CeA. Basal plasma corticosterone was similar for all three strains and repeated experience with the plus-maze had no effect on basal corticosterone levels or CRF mRNA levels in the paraventricular nucleus of the hypothalamus (PVN) for Wistar or WKY rats. Consistent with reported hyperactivity of the hypothalamopituitary adrenal axis of F344 rats with repeated stress, we observed elevated corticosterone following repeated exposure to the elevated plus-maze in F344 rats (p < 0.01) with a trend toward increased CRF mRNA levels in the PVN (p = 0.09). Heightened expression of CRF in the CeA of WKY rats may be involved in anxiety-like behaviors observed in this strain.     

Dopaminergic brain reward regions of Lewis and Fischer rats display different levels of tyrosine hydroxylase and other morphine- and cocaine-regulated phosphoproteins

We studied cyclic AMP-dependent protein phosphorylation in the mesolimbic and nigrostriatal dopamine systems of two genetically inbred rat strains, Lewis (LEW) and Fischer (F344) rats. These strains represent genetically divergent populations of rats that have been used to study possible genetic factors involved in a variety of biological processes. We found striking differences in levels of tyrosine hydroxylase, and several other phosphoproteins, in the mesolimbic, but not the nigrostriatal, dopamine system between the two rat strains. Interestingly, in Sprague-Dawley rats, these same phosphoproteins are altered by chronic morphine and chronic cocaine specifically in the mesolimbic dopamine system, generally thought to be a brain reward pathway that mediates some of the reinforcing actions of many drugs of abuse. As LEW and F344 rats have been reported to show different levels of preference for several types of drugs of abuse, the results are consistent with the possibility that these phosphoproteins may mediate aspects of drug reinforcement and contribute to individual differences in vulnerability to drug addiction.