WKHA rats with genetic hyperactivity and hyperreactivity to stress: a review

WKHA rats are a homozygous strain of hyperactive rats developed by successive selected inbreedings, starting from a cross of spontaneously hypertensive (SHR) rats with their normotensive control strain, WKY. WKHA express hyperactivity in a novel environment, as do SHRs, however their blood pressure is normotensive, thus they are potentially a more promising model of hyperactivity than the SHR. WKHA became homozygous in 1990 (20 strict brother/sister inbreedings), and they are currently in the F36 generation. Studies in collaboration with numerous colleagues have allowed us to describe a limited behavioral and neurochemical profile of WKHA rats. Their most prominent behaviors include hyperactivity in a novel environment, and a marked hyperreactivity to stress, both of which are also characteristic of SHRs. They differ from SHRs in other respects: WKHA are less aggressive, habituate more readily to a novel environment, and are less exploratory in a familiar environment than the SHR. Neurochemical studies have revealed changes in brain monoamine function in WKHA rats, particularly in frontal cortical norepinephrine and dopamine uptake, and they show marked changes in neuroendocrine responses in the hypothalamic/pituitary/adrenal axis, as well as altered POMC peptides in the pituitary anterior and posterior lobes. Molecular genetic studies by colleagues in Bordeaux have identified a quantitative trait locus for the hyperactivity/hyperreactivity trait of WKHA rats.

Genetic characterization of novel strains of rats derived from crosses between Wistar-Kyoto and spontaneously hypertensive rats, and comparisons with their parental strains

Two novel strains of rats have recently been generated from hybrid crosses of spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats. The breeding pairs chosen to create these strains were initially selected on the basis of two mutually exclusive phenotypic traits, so that the rats called WKHT are hypertensive but not hyperactive, whereas the rats called WKHA are hyperactive but not hypertensive. These strains have been refined by inbreeding on a strict brother-sister basis for more than 25 generations. To increase usefulness of these strains, we characterized them by use of genetic methods, including DNA finger-printing and simple sequence length polymorphism (SSLP) analyses. We found that these two novel strains are more closely related genetically to either SHR or WKY rats than the degree to which the latter two strains are related to one another; heterozygosities of SSLP marker alleles were extremely rare in WKHA and WKHT, indicating that these strains can be considered as truly inbred (in contrast to WKY rats from two sources); and it was almost always possible to match the SSLP marker alleles found in WKHA and WKHT rats with similarly sized alleles in the parental SHR and WKY alleles, indicating that the WKHA and WKHT strains constitute true mixes of the genomes of SHR and WKY rats. Furthermore, immunogenetic analyses indicated that WKY and WKHT rats belonged to the RT1 l haplotype, whereas SHR and WKHA rats belonged to the k haplotype. These results extend the usefulness of WKHA and WKHT rats for further genetic and physiologic studies.

Mutation of the trkB gene encoding the high-affinity receptor for brain-derived neurotrophic factor in stroke-prone spontaneously hypertensive rats

Brain-derived neurotrophic factor and its receptor, trkB, are thought to play a crucial role for protection against neuronal death induced by brain ischemia, such as in stroke. In the present study we found a missense mutation in the trkB gene from all of the five substrains of stroke-prone spontaneously hypertensive rats (SHRSP) that were examined. This mutation was not found in six out of seven hypertensive but stroke-resistant ancestral strains (SHR) of SHRSP, nor in any of seven strains of normotensive, non-stroke-prone strains. Hippocampal neurons, which are particularly vulnerable to damage in stroke, were shown to be more susceptible to ischemic damage in SHRSP than in either SHR or normotensive, stroke-resistant controls. The association of a mutated trkB gene with the stroke-prone genotype found in this study suggests that the trkB gene merits further study as a promising candidate gene for stroke.

Behavioral and neuroendocrine reactivity to stress in the WKHA/WKY inbred rat strains: a multifactorial and genetic analysis

Genetic factors have been shown to influence the nature and the intensity of the stress responses. In order to understand better the genetic mechanisms involved, we have studied the behavioral and neuroendocrine responses to novel environments in the WKHA/WKY inbred strains and we have investigated the genetic relationships between these traits in a segregating F2 intercross. The animals were submitted to behavioral tests known to provide both indices of activity and fear (activity cages, open field and elevated plus-maze). The plasma levels of prolactin, ACTH, corticosterone, glucose and renin activity were determined after a 10-min exposure to novelty. Our results showed that WKHA rats, compared to WKYs, were more active in a familiar as well as in novel environments. They exhibited also less anxiety-related behaviors and lower neuroendocrine responses. A principal component analysis performed on the behavioral F2 results defined three independent factors: general activity, anxiety and defecation, none of them being correlated with the neuroendocrine measures. Thus this study suggests that these different responses to stress are independent components that may have distinct molecular bases.

A major quantitative trait locus influences hyperactivity in the WKHA rat

The syndrome of hyperactivity describes behavioural disorders existing mainly in children and characterized by increased levels of motor activity, inattention and impulsivity. Overall the aetiology is poorly understood due to the heterogeneity of the pathology although psychological, biological and social factors acting singly or in concert are generally thought to be involved. In animal studies the observed hyperactivity phenotype results from relative participation of exploration, emotionality and general activity. Studies using brain lesions, neuropharmacology and gene knock-out strategies have shown that specific elements of the brain dopaminergic system can subserve hyperactivity. Evidence of a genetic contribution comes from family and twin studies but also from the ability to select divergent animal lines on the basis of their differential activity. The Wistar-Kyoto (WKY) and Wistar-Kyoto hyperactive (WKHA) rats are such strains--distinct for their low and high activity scores in a novel environment, respectively. Here, we report the detection of a major hyperactivity-related QTL on chromosome 8, explaining 29% of the variance of an intercross between these strains. This study represents the first behavioural QTL analysis in rat and provides a new starting point for biologically categorizing different forms of hyper-activity.

Effects of hypertension and propranolol upon aneurysm expansion in the Anidjar/Dobrin aneurysm model

Propranolol has been suggested to slow aortic aneurysm (AAA) expansion by a mechanism independent of simple blood pressure (BP) reduction. To investigate this hypothesis, we designed a series of experiments to examine the effects of hypertension and propranolol upon AAA expansion. Using an established animal model, we induced AAA in normotensive and genetically hypertensive rats by perfusion of the isolated infrarenal aorta with elastase for two hours. Systolic tail BP was monitored with a plethysmograph. AAA size was measured directly with a micrometer on postoperative days 7 and 14. All data are expressed as the mean +/- standard deviation (SD). BP (mmHg) was significantly higher in hypertensive rats: 164 +/- 15 versus 119 +/- 7 (p < 0.001). AAA were also significantly larger in hypertensive rats with a mean expansion rate (mm/day) nearly twice that of normotensive animals: 0.13 +/- 0.09 versus 0.07 +/- 0.03. In a second series of animals, propranolol treatment was compared to placebo. In those animals, hypertensive propranolol-treated rats had significantly smaller AAA than placebo-treated controls (p < 0.05). There was no difference in normotensive animals but these rats had an unexplained paradoxical rise in BP with treatment. In this model, hypertension increases the expansion rate of AAA. Propranolol reduced the size of AAA in hypertensive animals, at least in part because of a decrease in BP. Other possible mechanisms of propranolol's action may be operative and require further study.

Hemodynamic and biochemical characteristics of the aorta in the WKY, SHR, WKHT, and WKHA rat strains

This study was designed to characterize the hemodynamic and biochemical properties of the abdominal aorta in four genetically related inbred rat strains that express genetic hypertension and hyperactive behavior in varying combinations. These include (1) the spontaneously hypertensive rat (SHR), which is hypertensive, hyperactive, and hyperreactive to stress; (2) Wistar-Kyoto (WKY) rats, which express none of these traits; (3) WKHT rats, which are hypertensive but not hyperactive; and (4) WKHA rats, which are hyperactive and hyperreactive to stress, but normotensive. Together, these four strains allowed us to examine the structural and functional changes in the aorta in the hypertensive SHR, the most widely used animal model of genetic hypertension, while controlling for the variables of hyperactivity and hyperreactivity that are also expressed in the SHR. Four groups of animals of both sexes were studied: (1) WKY, n = 101, (2) WKHA, n = 33, (3) WKHT, n = 91, and (4) SHR, n = 28. Blood pressure (BP) was determined by tail plethysmography as well as direct intraarterial monitoring under anesthesia. Fixed specimens were prepared for histologic analysis and the wall thickness determined morphometrically. Quantification of soluble tissue protein, elastin, and collagen in the aortic tissue was determined by measuring leucine (leu), hydroxyproline (HP/leu), and desmosine (DES/leu). The hypertensive strains (SHR and WKHT) had significantly higher tail BP than the normotensive strains (WKY and WKHA)-WKY: 128.7 +/- 22.3; WKHA: 126.7 +/- 14.6; WKHT: 162.8 +/- 21.2; SHR: 164.2 +/- 36.1 (p < 0.0001). Additionally, intraaortic diastolic BP and mean BP were higher in SHR rats than in WKHT. Morphometric studies showed the media thickness in the SHR rats was significantly greater than in the WKY and WKHA rats and no different than in the WKHT rats. Significantly less of the aortic wall protein was present as elastin in the hypertensive rats (SHR and WKHT), as well as the hyperactive rats (WKHA), compared to rats that had neither trait (WKY). These studies provide new information regarding aortic structure and function in genetic hypertension using inbred strains to control for the hyperactivity/hyperreactivity traits that coexist with hypertension in the SHR. They reveal that hypertensive aortas have altered matrix proteins that cannot be explained simply on the basis of blood pressure alone.

Circadian timekeeping in hyperactive and hypertensive inbred rat strains

Inbred strains have been used to study genetic and physiological relationships among different aspects of circadian timekeeping, as well as relationships between circadian rhythmicity and other strain-specific traits. The present study characterized several features of circadian timekeeping in genetically hyperactive (WKHA) and genetically hypertensive (WKHT) inbred strains, derived from spontaneously hypertensive (SHR) and Wistar-Kyoto (WKY) rats. WKHAs and WKHTs differed in free-running period, steady-state entrainment to light-dark cycles, and photic phase shifting, and relationships among these measures were consistent with previous studies of species, strain, and individual differences. Because both WKHTs and SHRs show short circadian periods relative to their respective comparison strains, this trait may cosegregate genetically with hypertension. In contrast, because WKHAs and SHRs show similar photic entrainment and phase shifting, these circadian functions may cosegregate with open-field hyperactivity. Finally, because neither WKHAs nor WKHTs show the SHR's excessive levels of home-cage running wheel activity, this trait is not related to either hypertension or open-field activity. Further work would be required to elucidate specific genetic and/or physiological linkages among these variables.

Mutation of low affinity nerve growth factor receptor gene is associated with the hypertensive phenotype in spontaneously hypertensive inbred rat strains

We previously reported a missense mutation in the low affinity nerve growth factor receptor (LNGFR) gene of spontaneously hypertensive rats (SHR), proposing this gene as a promising candidate in genetic hypertension. In this study we provide further support for implicating this gene in genetic hypertension using two new inbred strains, WKHT and WKHA rats. These strains originated from crossbreeding SHR rats with normotensive Wistar-Kyoto rats (WKY): WKHT rats are hypertensive but not hyperactive, and WKHA rats are hyperactive but not hypertensive. Nucleotide sequence analysis of the LNGFR gene revealed that WKHT has the same mutation as SHR, whereas WKHA has the normal sequence, as seen in WKY. These results support our original hypothesis that the mutated LNGFR gene is linked to hypertension, since the mutation had co-segregated with the hypertensive trait, and not hyperactivity trait of SHR.

Anti-CD 18 monoclonal antibody slows experimental aortic aneurysm expansion

PURPOSE

Inflammation has been implicated as a contributing factor in the expansion of abdominal aortic aneurysms (AAA). To test this hypothesis, we examined the effects of a monoclonal antibody (MAB) to the leukocyte CD18 adhesion molecule on the expansion of experimental AAA.

METHODS

Aneurysms were induced by perfusion of an isolated segment of the infrarenal aorta with elastase in 22 normotensive (WKY) and 17 genetically hypertensive (WKHT) rats. Animals of both strains were randomly allocated to control or MAB-treated groups (MAB, 5 microgram/100 gm body weight intraperitoneally, daily, beginning on the operative day for a total of four doses). The activity of the MAB against rat leukocytes had first been determined by in vitro immunofluorescence flow cytometry. Aortic size was directly measured initially and on day 14. At that time, a segment of aorta was stained with hematoxylin and eosin and mononuclear leukocytes and neutrophils were counted in each of 10 microscopic fields (400X).

RESULTS

The initial aortic size in all animals was 1.11+/-0.15 mm. All groups developed aneurysms significantly larger than the initial aortic size (p<0.01). However, the MAB-treated animals had significantly smaller aneurysms than the untreated controls (mm): WKY: 3.63+/-1.26, WKY-MAB: 2.08+/-0.30, WKHT: 4.54+/-1.86, WKHT-MAB: 2.37+/-0.40, p<0.0001. There also were significantly fewer monocytes in the MAB-treated normotensive rats: WKY:35.5+/-29.9, WKHT:40.6+/-28.8, WKY-MAB: 8.9+/-8.5, WKHT-MAB: 32.3+/-25.7, p=0.03. Neutrophil counts did not differ significantly between the groups.

CONCLUSIONS

Treatment with anti-CD18 monoclonal antibody slows the expansion of AAA in this experimental model. The associated inflammatory process at day 14, as indicated by monocyte infiltration, is reduced, but this effect may be opposed by the presence of hypertension. Further evaluation of the role of leukocytes and adhesion molecules in the expansion of AAA is warranted.

Enhanced vascular neuropeptide Y-immunoreactive innervation in two hypertensive rat strains

Considerable evidence indicates an enhanced sympathetic innervation of resistance arterial smooth muscle in the spontaneously hypertensive rat (SHR) compared with its normotensive Wistar-Kyoto (WKY) control. In addition to sympathetic hyperinnervation, an increased vascular innervation by neuropeptide Y-containing fibers, which are known to exert a vasoconstrictive and trophic action in vascular smooth muscle, has also been described. In addition to genetic hypertension, the SHR expresses hyperactive behavior and hyperreactivity to stress. To determine whether the enhanced neuropeptide Y-immunoreactive vascular innervation is specifically associated with hypertension and/or these behavioral abnormalities, four genetically related, inbred rat strains were used: SHR, which are hypertensive and hyperactive; WKY rats, which are neither hypertensive nor hyperactive; WKHA, which are hyperactive but normotensive; and WKHT, which are hypertensive but not hyperactive. The present study demonstrated that whereas the hypertensive strains (SHR and WKHT) exhibited smooth muscle hypertrophy in both superior mesenteric and caudal arteries in adulthood (10 months) but not at a prehypertensive age (1 month), both arteries exhibited significantly increased neuropeptide Y-immunoreactive innervation at both ages. It was further observed that the mesenteric artery in WKHA, a normotensive strain, had significant smooth muscle hypertrophy at 10 months; however, neuropeptide Y innervation in this artery was no different from that of WKY controls. The findings indicate that there is a cosegregation of neuropeptide Y hyperinnervation of the vasculature with the hypertensive phenotype, evident as early as 1 month of life in the hypertensive strains, and this should be considered further as a contributory factor in genetic hypertension.(ABSTRACT TRUNCATED AT 250 WORDS)

Expansion of aortic aneurysms is reduced by propranolol in a hypertensive rat model

PURPOSE

It has been suggested that propranolol has unique effects that slow aneurysm expansion by remodeling the structural proteins of the aorta. These effects are believed to be independent of blood pressure reduction, a hypothesis we tested in this investigation with a rat model of abdominal aortic aneurysm (AAA).

METHODS

With an established model, AAA were induced in normotensive Wistar-Kyoto (WKY) rats and genetically hypertensive Wistar-Kyoto (WKHT) rats by perfusing an isolated segment of the infrarenal aorta with elastase. A propranolol dose-response was studied for each strain: (1) saline solution controls (n = 18); (2) propranolol, 10 mg/kg subcutaneously (n = 18); (3) propranolol, 30 mg/kg (n = 14). Systolic blood pressure was determined by tail plethysmography before operation and on day 14, as well as by direct recording at surgery and on day 14. Rats were killed at 14 days, and aneurysm diameter was measured.

RESULTS

The initial tail BP was 129 +/- 22 mm Hg in WKY animals and 158 +/- 21 mm Hg in WKHT animals (p < 0.0001). Tail BP and intraaortic systolic, diastolic, and mean blood pressure (BP) were not significantly decreased by propranolol treatment in either strain of rats. However, BP tended to rise in WKY rats, whereas it fell slightly in WKHT rats. Initial aortic size in all animals was 1.06 +/- 0.12. The final aortic size in untreated, hypertensive rats was more than twice that of untreated normotensive controls: 1: WKHT, 3.0 +/- 0.73 mm, 1: WKY, 6.9 +/- 3.5 mm (p < 0.01). After treatment with both doses of propranolol, hypertensive aneurysms were significantly smaller than the untreated WKHT group (p < 0.05) and not significantly different from aneurysms in all groups of normotensive animals: 2: WKY, 3.1 +/- 1.13 mm, 2: WKHT, 4.0 +/- 1.81 mm; 3: WKY, 4.1 +/- 0.41 mm, 3: WKHT, 2.9 +/- 1.24 mm. There was no significant difference in aortic size between the three normotensive WKY groups.

CONCLUSIONS

Hypertension increases the size of aortic aneurysms in this experimental model. Propranolol significantly reduces the size of experimental AAA in hypertensive animals independently of the dose and by a mechanism that may be unrelated to simple BP reduction.

Blood cell changes in spontaneously hypertensive rats are not all associated with the hypertensive phenotype

OBJECTIVE

To search for cosegregation of a change in specific blood cells with either the hypertension or the hyperactivity phenotype in spontaneously hypertensive rats (SHR), Wistar-Kyoto (WKY) rats and two new inbred strains.

DESIGN AND METHODS

Standard hematological procedures were used to examine erythrocytes, leukocytes and platelets in blood drawn from adult SHR, WKY rats and the two new inbred strains of rats.

RESULTS

The hypertensive strains exhibited significant erythrocytosis, microcytosis, lymphocytosis and monocytosis relative to the normotensive strains. The hyperactive strains exhibited significant neutrophilia and increased platelet count relative to the non-hyperactive strains.

CONCLUSION

Not all of the differences in blood cells described originally in SHR versus WKY rats were associated with the inheritance of hypertension. The changes in the lymphocytes and in the erythrocytes should be examined as possible factors in the pathophysiology of hypertension.

Anterior pituitary proopiomelanocortin expression is decreased in hypertensive rat strains

Studies comparing neuroendocrine differences between the spontaneously hypertensive rat (SHR) and the normotensive Wistar-Kyoto (WKY) strains have suggested altered anterior pituitary corticotrope expression of POMC associated with the development of hypertension in SHR animals. One major difficulty in comparing the SHR and WKY strains is that the two strains exhibit genetic differences unrelated to blood pressure status, because inbred in the SHR genome is a profile of behavioral characteristics different from those in the WKY, including hyperactivity in a novel environment and hyperreactivity in responding to stress. The present studies examine two new inbred rat strains, the WKHT and WKHA, which independently express the hypertension and behavioral traits, respectively. Together with the SHR and WKY, these genetically related, homozygous strains permit a more definitive means of examining the neuroendocrine correlates of either hypertension or behavior. The adult (5-month-old) male anterior pituitary gland content of the POMC peptides beta-endorphin and ACTH was decreased approximately 50% in the SHR and WKHT strains compared to that in the WKY strain, whereas hormone levels in the WKHA strain were not significantly different from those in the WKY strain. Reduced POMC peptide levels were, therefore, specifically associated with the hypertensive trait. Hormone content in prehypertensive weanling (5- to 7-week-old) SHR and WKHT animals was also reduced approximately 35% compared to that in WKY animals. Northern blot analysis identified a 45% decrease in POMC mRNA expression in the hypertensive SHR and WKHT strains, which paralleled the changes in tissue hormone content. Using both immunocytochemistry and in situ hybridization histochemistry, the number of labeled cells per unit area of tissues section was reduced approximately 45% in anterior pituitary tissues from SHR and WKHT rats compared to that in WKY tissues. The levels of POMC mRNA per cell, determined by quantitative densitometry, were not statistically different in the anterior pituitaries of WKHT, SHR, and WKY rats. The decrease in hormone content and POMC mRNA levels may, thus, reflect decreased anterior pituitary gland corticotrope populations. Although POMC peptide levels in the anterior pituitaries of adult WKHA animals were not significantly different from those in WKY animals, the morphological studies demonstrated a 30% increase in the corticotrope population in the WKHA strain. In contrast, POMC mRNA levels in WKHA animals were decreased 30%, and the amount of POMC mRNA per corticotrope was decreased approximately 35% compared to that in WKY, SHR, and WKHT tissues.(ABSTRACT TRUNCATED AT 400 WORDS)

Psychoneuroendocrine profile associated with hypertension or hyperactivity in spontaneously hypertensive rats

The behavioral and neuroendocrine reactivity to a novel environment (open field) and the adrenocorticotropic hormone (ACTH)/corticosterone response to a corticotropin-releasing factor (CRF) challenge were measured in 2-mo-old rats from four inbred strains derived from the Wistar-Kyoto rat: spontaneously hypertensive rats (SHRs), hypertensive and behaviorally hyperactive to novelty; WKY, neither hypertensive nor hyperactive; WKHA, hyperactive but normotensive; and WKHT, only hypertensive. The ACTH response to CRF was much lower in SHRs than WKYs, this reduced reactivity being clearly associated with the hyperactivity trait, since it was present in the WKHA and absent in the WKHT strain. On the other hand, the ACTH/corticosterone response to a psychological stimulus (open field) could not clearly discriminate the four strains. The largest difference was found in the prolactin response. Post-open-field levels were much lower in the WKHA (27.11 +/- 4.69 ng/ml) than in the parent WKY strain (83.65 +/- 6.84 ng/ml), the hypertensive strains having intermediate levels (WKHT: 58.05 +/- 7.65 ng/ml; SHR: 64.13 +/- 7.19 ng/ml). Other differences were also found in the levels of aldosterone and renin activity. These results indicate that these strains are an excellent model to study neuroendocrine correlates of hypertension and hyperactivity, which are associated in the SHR strain and may be of interest for the study of the association between neuroendocrine and behavioral characteristics.

Psychosocial stress can induce chronic hypertension in normotensive strains of rats

We report on five 6-month experiments during which five colonies of four male and four female rats were exposed to psychosocial stress. Monthly blood pressure measurements by a tail-cuff method showed a modest (10 mm Hg) increase in two studies using Sprague-Dawley rats. In two further studies using the more aggressive Long-Evans strain, terminal direct carotid arterial pressures were taken as well, and in one study the differences exceeded 20 mm Hg. A fifth study used the Wistar-Kyoto, hyperactive (WKHA) strain developed by Hendley, and no differences were observed. Heart and adrenal weights; adrenal catecholamine synthetic enzymes; and heart, aortic, and kidney histology were measured and showed significant changes, which for the most part paralleled blood pressure changes. Social instability and the associated blood pressure changes were made more severe by periodic mixing of males from different colonies. This had no effect on the peaceable WKHA rats, some effect on the Sprague-Dawley rats, and a severe effect on the Long-Evans rats. The WKHA rats failed to show blood pressure changes despite stress-induced increases in heart and adrenal weights. Thus, different types of psychosocial stress and different genetics combine to induce a variety of neuroendocrine changes, not all of which necessarily lead to increased blood pressure.

Hypertension accelerates the growth of experimental aortic aneurysms

Hypertension has long been suspected to increase the growth rate of abdominal aortic aneurysms (AAA), but there is little experimental evidence to support this hypothesis. Using an established model, aneurysms were induced in normotensive Wistar-Kyoto (WKY) rats and in a unique strain of genetically hypertensive Wistar-Kyoto (WKHT) rats by perfusing an isolated segment of the infrarenal aorta with elastase (n = 14, each group). Aortic diameter was measured with a micrometer and systolic blood pressure (sBP) determined by tail plethysmography. Rats were killed at 7 or 14 days, aneurysm diameter was measured, and aneurysms were examined histologically. Systolic blood pressure was significantly higher in WKHT rats (164 +/- 15 mm Hg) compared to WKY animals (119 +/- 7 mm Hg, P < 0.001). Initial aortic size was 1.10 +/- 0.02 mm in the two groups. Aneurysms in the hypertensive animals were significantly larger at Day 7 (WKY, 2.31 +/- 0.09 mm; WKHT, 2.54 +/- 0.22 mm; P = 0.02) and Day 14 (WKY, 2.36 +/- 0.25; WKHT, 3.45 +/- 0.89; P = 0.001). Overall, the mean AAA growth rate of the WKYHT group was nearly twice that of the WKY group: 0.13 +/- 0.09 mm/day vs 0.07 +/- 0.03 mm/day, (P = 0.004). Growth rates were also positively correlated with sBP (r = 0.82, P < 0.0001). Both groups showed elastic lamellar disruption and inflammatory cell infiltration within the wall of the aorta. As demonstrated in this experimental model, hypertension does indeed increase the rate of growth of AAA.

Renal dopamine-1 receptors in hypertensive inbred rat strains with and without hyperactivity

Renal dopamine-1 (DA-1) receptors are involved in the regulation of sodium transport in several nephron segments, including the proximal convoluted tubule (PCT). DA-1 receptors in the PCT and cortical collecting duct of normotensive rats are linked to the stimulation of adenylyl cyclase (AC). We have reported a defect in the DA-1 receptor/AC coupling in the PCT of the spontaneously hypertensive rat (SHR) of the Okamoto-Aoki strain. Hyperactivity and hypertension are both expressed in the SHR. To determine if the DA-1 receptor coupling defect is associated with hyperactivity or hypertension, we studied the DA-1 receptor in the PCT of two new inbred rat strains derived from the SHR: the hyperactive WKHA and the hypertensive WKHT rat. Tail-cuff blood pressures taken at 4 weeks indicated that WKHT rats were not hypertensive (86 +/- 3 mm Hg, n = 6), whereas at 12 weeks systolic pressures in both SHR and WKHT rats exceeded 150 mm Hg. Hyperactivity, however, was noted in WKHA rats even at this early age. Basal AC activity was similar in WKHA and WKHT PCT in either age group. In the older rats, the DA-1 agonist fenoldopam (10(-7) mol/L) stimulated AC activity in WKHA (70.6 +/- 16.1 fmol per 3 mm PCT per 20 minutes, n = 3) but not in WKHT PCT (43.3 +/- 5.3 fmol per 3 mm PCT per 20 minutes, n = 4). Gpp(NH)p (10(-5) mol/L), a nonhydrolyzable GTP analogue, stimulated AC activity to a similar extent in WKHA and WKHT PCT.(ABSTRACT TRUNCATED AT 250 WORDS)

Regional differences in brain norepinephrine and dopamine uptake kinetics in inbred rat strains with hypertension and/or hyperactivity

High-affinity uptake of norepinephrine (NE) and dopamine (DA) were determined in synaptosomes of brain regions from four genetically related inbred rat strains, all derived from the Wistar-Kyoto rat: SHR, WKY, WKHA and WKHT strains. SHRs express hypertension and hyperactivity, WKHAs express hyperactivity alone, WKHTs express hypertension alone, and WKYs are neither hypertensive nor hyperactive. Significant increases in NE uptake, primarily in Vmax, in cerebral cortical areas and the cerebellum, were associated with the hypertensive trait. Significant increases in DA uptake Vmax in the frontal cortex were associated with the inheritance of hyperactivity among these strains. A limited study in SHRs indicated that DA uptake in the frontal cortex increased with age, and that males did not differ from females. No changes in DA uptake in the neostriatum were found with respect to either strain, or age or sex. These findings revealed changes in brain catecholamine neuronal function that are of relevance to both hypertension and hyperactivity. This was made possible by the availability of WKHA and WKHT, in addition to WKYs, as appropriate controls for the SHR.

Behavior of hypertensive and hyperactive rat strains: hyperactivity is not unitarily determined

The spontaneously hypertensive rat (SHR) is behaviorally hyperactive relative to the Wistar-Kyoto rat (WKY). By breeding SHR with WKY, followed by inbreeding, two new strains have been developed in which hypertension seems to be separated from hyperactivity to novel stimuli: the WKHT and the WKHA strains. The main purpose of the present study was to determine which behavioral characteristics of SHR have been dissociated from the hypertensive trait in the WKHA strain. Male SHR, WKY, WKHT, and WKHA were subjected to three protocols: 1) Two forced-exploration tests, where the results showed that both the SHR and the WKHA rats were hyperactive. 2) A free-exploration open field, where the SHR was more active than the other strains, showing shorter latencies to leave the home cage, spending more time in the field, ambulating and rearing more. Furthermore, the WKHT behavior was more similar to the SHR behavior than the WKHA behavior. 3) A two-component schedule of reinforcement, where one component (fixed-interval 2 min) was signaled by houselight on and the other (extinction, EXT) by houselight off. In this test, the SHR behavior was markedly different from that of the three other strains: the fixed-interval scallop, the accelerated responding towards the end of the interval, was steeper in SHR than in the other groups. The SHR emitted more responses during the extinction component of the schedule. The SHR hyperactivity was dependent upon the reinforcement value of the water deliveries and was increased even further by sensory-reinforcing respones feedback lights. Thus, the hyperactivity of the WKHA strain seems to be less pervasive than that of the SHR.(ABSTRACT TRUNCATED AT 250 WORDS)

Interstrain aggression in hypertensive and/or hyperactive rats: SHR, WKY, WKHA, WKHT

Four inbred rat strains, all derived from Wistar-Kyoto (WKY) rats, express hypertension and hyperactivity in all combinations: SHRs have both traits, WKYs have neither, WKHAs are hyperactive/normotensive, and WKHTs are hypertensive/normoactive. Rats of the four strains were tested for aggression, at one time only, by pairing subjects of same sex, same age, but different strain, in a novel arena, i.e., on neutral ground, for three consecutive, 5-min observation periods. Total aggression scores were highest in females, highest in the first 5-min period, and lower at 7-9 months than at younger ages. Allogrooming was more frequently observed than other types of aggression, such as attacks, mounts, aggressive postures, and blocks. Allogrooming scores were significantly elevated in the hypertensive strains, especially WKHT, and very low in the hyperactive strains, especially WKHA. The other forms of aggression were significantly higher in females with hyperactivity. It was concluded that interstrain aggression, as seen in SHRs and WKYs, is differentially expressed by two new strains genetically derived from them. Furthermore, no one strain among these four expresses all components of the behavioral responses seen in this form of aggression.

Hypertrophy of stellate ganglion cells in hypertensive, but not hyperactive, rats

The dendritic complexity of peripheral autonomic neurons is positively matched with the size of the target they innervate, apparently by trophic interactions with the target (D. Purves, W. D. Snider, and J. T. Voyvodic. Nature Lond. 336: 123-128, 1988). We have asked whether the vascular hypertrophy associated with hypertension is accompanied by dendritic hypertrophy of sympathetic ganglion cells. To do this, we examined the morphology of stellate ganglion cells in the spontaneously hypertensive rat (SHR), its normotensive control Wistar-Kyoto rat (WKY), and two new strains derived from the SHR that independently express the hypertensive phenotype of the SHR (WKHT) and the behavioral hyperactivity present in the SHR (WKHA). Cells were examined by intracellular staining with horseradish peroxidase in in vitro preparations of the ganglia. Carotid arterial wall size was also examined. Significant hypertrophy of both the carotid arterial wall and stellate ganglion cell dendrites was observed in the two hypertensive strains (SHR and WKHT) but not in either of the normotensive strains (WKY and WKHA). This increased total dendritic length of stellate ganglion cells associated with hypertension provides a greater target area for preganglionic innervation that may result in hyperinnervation of these cells.

Two new inbred rat strains derived from SHR: WKHA, hyperactive, and WKHT, hypertensive, rats

Two new strains of inbred rats have been developed. One, WKHA, exhibits hyperactivity, and the other, WKHT, exhibits hypertension. Both of these traits are expressed in the SHR. By crossing spontaneously hypertensive rats (SHRs) with Wistar-Kyoto (WKY) controls, followed by recombinant selected inbreeding, we succeeded in genetically separating the hyperactivity from the hypertension in two new strains. Longitudinal studies indicate a persistence of hypertension without hyperactivity in WKHTs, and hyperactivity without hypertension in WKHAs, over at least 1 year. Ventricular enlargement, another characteristic of SHRs, was observed in adult WKHTs after the onset of hypertension; however, ventricles were already enlarged in normotensive WKHAs at 6 wk. The emergent behavioral profile of WKHAs indicates that they retain the hyperactivity trait and hyperreactivity to stress, and not some of the other behaviors of SHRs, such as poor habituation. Studies in WKHTs suggest that they are an improvement over SHRs as a model of genetic hypertension as they lack some prominent behavioral abnormalities. Nevertheless, the four genetically related strains (WKHA, WKHT, SHR, and WKY), used together, are considered most appropriate for seeking correlations of biological differences with either hypertension or hyperactivity.

Two new Wistar-Kyoto rat strains in which hypertension and hyperactivity are expressed separately

Two inbred strains have been developed from a cross between SHR and WKY. WK-HTs are hypertensive but not hyperactive, and WK-HAs are hyperactive but normotensive. Together with SHR (that express both traits) and WKY (expressing neither trait) we used four strains to follow correlations of biological changes with the expression of hyperactivity or hypertension. We show that the well known sympathetic hyperreactivity of SHRs to acute stress is associated with the hyperactivity trait and not the hypertension among the four strains. Similarly, the well known ventricular hypertrophy in SHRs is more prominent among the hyperactive strains than the hypertensives. Examination of regional brain amine levels revealed an imbalance in forebrain serotonin transmission in the hyperactive strains, and no significant correlations with hypertension. On the other hand, neuropeptides in brainstem and spinal cord revealed a decrease, in hypertension, in neuropeptide Y and PNMT content of terminals of C1 fibers that innervate the spinal cord sympathetic outflow. Also, the two hypertensive strains showed increased TRH-and proctolin-like immunoreactivity in fibers that innervate the C1 cells in the rostral ventrolateral medulla. These findings illustrate the unique advantage provided by WK-HA and WK-HT strains as additional controls for SHRs in studying hypertension and hyperactivity.

Association between cardiovascular reactivity to stress and hypertension or behavior

The spontaneously hypertensive rat (SHR) exhibits increased cardiovascular reactivity (CVR) to environmental stress and behavioral hyperactivity relative to the Wistar-Kyoto rat (WKY). This study sought to determine whether enhanced CVR to stress in the SHR is related to hypertension or to behavioral hyperactivity. By breeding SHR with WKY, followed by inbreeding, E. D. Hendley has developed two strains in which the hypertensive trait seems to be separated from the hyperactivity trait: the Wistar-Kyoto hypertensive (WK-HT) and the Wistar-Kyoto hyperactive (WK-HA) strains. Male SHR, WKY, WK-HT, and WK-HA rats were implanted with intravascular catheters and Doppler flow-velocity probes to record arterial pressure, heart rate (HR), and changes in regional vascular resistances. Five days after surgery, the rats were subjected to air-jet stress and pharmacological interventions. The hyperactive strains (SHR and WK-HA) exhibited enhanced pressor, renal, and mesenteric responses to stress, and higher HRs under all conditions, even after autonomic blockade. Both hypertension and hyperactivity were associated with reduced baroreceptor sensitivity. These data indicate that CVR to stress is related to behavioral traits.

Extracellular ATP stimulates norepinephrine uptake in PC12 cells

This study examined the effects of extracellular ATP on norepinephrine (NE) uptake, using PC12 cells as a model of noradrenergic neurons. Previous experiments with synaptosomes led to the hypothesis that extracellular ATP can regulate NE uptake via an ecto-protein kinase. In the present study, we examined the high-affinity uptake of NE (referred to as uptake 1) in PC12 cells in the presence of varying concentrations of extracellular ATP. In the presence of Ca2+, low concentrations of ATP (0.1 microM) increased uptake 1 by approximately 36%. This increase could be mimicked by adenosine-5'-O-(3-thiotriphosphate) tetralithium salt (ATP gamma S), an analogue of ATP which can be utilized by protein kinases, and not by 5'-adenylylimidodiphosphate tetralithium salt, a nonhydrolyzable analogue of ATP, GTP, ADP, and adenosine also had no effect on uptake 1. Preincubation of the cells with NE and ATP gamma S, followed by washing and assaying NE uptake 30 min later, resulted in a persistent increase in uptake 1. Similar pretreatment with ATP did not show this increase; however, simultaneous pretreatment with ATP and ATP gamma S blocked the activation produced by ATP gamma S alone. Kinetic analysis showed that ATP gamma S pretreatment produces an increase in the Vmax of uptake 1 without altering the apparent Km for NE. These results support the hypothesis that extracellular ATP can regulate NE uptake via an ecto-protein kinase.

Brain monoamines and metabolites in hypertensive and hyperactive rat strains

Monoamines and metabolites were measured by HPLC-EC in brain regions of four Wistar-Kyoto derived rat strains, in whom the traits of genetic hypertension or hyperactive behavior were expressed together (SHR), separately (WK-HT and WK-HA strains, respectively), or not at all (WKY). These genetically related inbred strains were used to allow more discrete correlations between neurochemical changes and the hypertensive and/or hyperactive state, than was hitherto possible using SHR and WKY metabolite levels were present in the six brain regions examined, however, no correlations with hypertension were observed. Limited correlations were seen between hyperactivity and forebrain serotonergic systems. These findings demonstrate that neurochemical differences between SHR and WKY may be erroneously attributed to the hypertension and/or hyperactivity of the SHR, unless additional genetic control strains, such as WK-HT and WK-HA rats are utilized.

Regulation of norepinephrine uptake by adenine nucleotides and divalent cations: role for extracellular protein phosphorylation

This study examined the hypothesis that ATP, released together with norepinephrine (NE) from brain noradrenergic nerve terminals, may serve as a cosubstrate for an extracellular protein phosphorylation system that regulates the reuptake of the transmitter, NE. The possible regulation of high-affinity uptake (uptake 1) of [3H]NE by divalent cations and ATP, both of which are involved in protein phosphorylation, was examined in rat cerebral cortical synaptosomes. A marked inhibition of uptake 1 by 5'-adenylylimidodiphosphate [App(NH)p], a nonhydrolyzable, competitive antagonist of ATP, was observed. A similar inhibition of uptake was observed when Ca2+ and Mg2+ were both omitted from the incubation medium. App(NH)p distinguished the actions of Ca2+ from those of Mg2+: Ca2+-stimulated uptake 1 was blocked by App(NH)p; Mg2+-stimulated uptake was not. In parallel experiments, the patterns of protein phosphorylation in crude and purified preparations of synaptosomes were examined under conditions similar to those used in uptake assays. A striking correlation was found between the inhibition of uptake 1, by either App(NH)p or Ca-omission, and inhibition of the phosphorylation of one specific, 39,000-dalton, Ca2+-dependent, protein component in synaptosomes. This 39K protein was distinct from the alpha subunit of pyruvate dehydrogenase, a mitochondrial protein of similar electrophoretic mobility. These findings are consistent with the possibility that an ectokinase on synaptosomes utilizes extracellular ATP and Ca2+ in phosphorylating a protein(s) associated with the regulation of NE uptake.

Sympathetic-adrenal medullary response to stress in hyperactive and hypertensive rats

Sympathetic-adrenal medullary hyperreactivity to acute stress, measured as an exaggerated elevation of plasma epinephrine and norepinephrine levels in response to footshock, was examined in four genetically related, inbred rat strains, all derived from the Wistar-Kyoto rat (WKY). These four strains are endowed with the traits of hypertension and behavioral hyperactivity, expressed either together (in SHR), or separately in two new strains (Wistar-Kyoto hyperactive rats, WK-HA, and Wistar-Kyoto hypertensive rats, WK-HT), or not at all (in WKY). Male rats of the SHR, WKY, WK-HA and WK-HT strains were subjected to acute footshock stress in order to determine whether the previously reported hyperreactivity of the SHR is attributable to the hypertensive trait, or to the behavioral hyperactivity trait, both of which are characteristic of the SHR. Plasma catecholamine levels were determined prior to, immediately following, and 5 min following acute footshock stress. We report here that the WK-HA strain (hyperactive but not hypertensive) exhibited the hyperreactivity characteristic of SHRs, and not the WK-HT strain (hypertensive but not hyperactive). We conclude that the exaggerated sympathetic-adrenal medullary response to acute stress is associated with the hyperactivity trait and not with hypertension among these congenic rat strains.

Behavioral and metabolic effects of sucrose-supplemented feeding in hyperactive rats

Two hyperactive rat strains [spontaneously hypertensive rats (SHR) and SHR-Wistar-Kyoto cross (WK-HA)] and their nonhyperactive genetic control strain (Wistar-Kyoto) were fed ad libitum sucrose-supplemented rat chow, or chow alone in controls, to determine the effects of dietary sugar on behavior. The diets were given either overnight (acute sugar) or for 14-18 days (chronic sugar), and testing was carried out on the morning after each of the dietary schedules. The metabolic studies revealed significant strain, sex, and age differences in appetite for sucrose, caloric intake, postprandial plasma levels of glucose and insulin, and weight gain after sucrose feeding. The findings indicate that sugar feeding led to increased plasma glucose and insulin levels; however, total caloric intake was decreased, and less weight gain was observed than in chow-fed controls, particularly among the hyperactive strains. In behavioral tests, sugar feeding did not alter spontaneous activity levels in any of the strains after either acute or chronic diets. There were also no significant effects of sucrose consumption on spatial learning and memory in a plus-shaped maze as determined by use of a shock-avoidance paradigm. The only significant behavioral effects of sucrose observed were an impairment in habituation and distractibility among the WK-HA females, the most hyperactive group among these strains.

Inbreeding of Wistar-Kyoto rat strain with hyperactivity but without hypertension

A genetic inbreeding program using Wistar-Kyoto rat strains as progenitors was used to combine the hyperactivity trait of the spontaneously hypertensive rat (SHR) with the normotensive trait of the WKY genetic control strain. From an SHR X WKY cross we produced a gene-assorting F2 population from which selected brother-sister matings were carried out through seven successive inbred populations. This program produced a new strain of hyperactive rats with normotensive mean systolic blood pressure levels, and we have designated the new strain as the Wistar-Kyoto hyperactive (WK/HA) rat. Another behavioral characteristic of the SHR rat, poor habituation in a nonreinforcing novel environment, did not appear as a characteristic trait of the new strain of WK/HA rats, suggesting a separate underlying genetic basis for the two traits that had been apparently fortuitously fixed in the SHR genotype as a result of intensive inbreeding of that strain. The new WK/HA strain, together with the WKY control strain, is considered as more suitable for subjects in studying hyperactivity in rats than the original SHR strain with its concomitant hypertension and poor habituation traits.

Age, sex and strain differences in activity and habituation in SHR and WKY rats

The highly inbred strain of Wistar-Kyoto spontaneously hypertensive rat (SHR) and its normotensive, genetic control (WKY) were examined with respect to strain differences in spontaneous activity scores in a novel environment (small activity cage) and in ability to habituate to that environment. These behaviors were examined in experimentally naive rats, 197 SHR and WKY, males and females, at varying ages from 4 to 56 weeks, in order to determine whether there are sex and age differences in addition to the well-known strain differences in these behaviors. Total activity scores, determined in a 15 min test in the activity cage, were higher in SHR than WKY rats; females were significantly more active than males in either strain, and activity scores varied significantly with age both within strains and between strains. Ability to habituate to the test cage was determined by repeating the 15 min activity test at hourly intervals for three additional trials on the same day. The results indicate that the SHR, males and females and at all ages tested, habituate poorly if at all to the test cage as compared with WKY rats. Moreover, despite the variability of baseline activity scores (first trial) observed across ages, sexes and strains, the habituation patterns of either strain remained relatively fixed throughout the first year of life.

Genetically related rats with differences in hippocampal uptake of norepinephrine and maze performance

The spontaneously hypertensive rat (SHR) and its progenitor strain, the Wistar-Kyoto (WKY) display marked differences in brain catecholamines and behavior. The behavioral differences are suggestive of alterations in hippocampal function and, in particular, the noradrenergic input to the hippocampus. To test these hypotheses we have analyzed the performance of the SHR and WKY in a spatial memory maze task that is specific to hippocampal function and determined the kinetics of norepinephrine (NE) uptake in synaptosomal preparations of the hippocampus. We have found that WKYs exhibit an abnormally strong bias tendency in T-maze arm preference that influences the rate of acquisition and the final level of maze performance. We have also found differences in noradrenergic uptake in hippocampal synaptosomes. WKYs exhibit higher NE uptake rates and higher kinetic constants for NE uptake when compared with SHRs, suggesting that strain differences in noradrenergic function may contribute to the observed behavioral differences.

Activation of adenylyl cyclase by preincubation of rat cerebral-cortical membranes under phosphorylating conditions: role of ATP, GTP, and divalent cations

The effects of preincubation under phosphorylating conditions on adenylyl cyclase activity were studied in preparations containing synaptic membranes from rat cerebral cortex. Preincubation of the membranes with 2 mM ATP and 10 mM MgCl2 resulted in a 50% increase of adenylyl cyclase activity which withstood sedimentation and washing. This activation was maximal after 5 min of preincubation, was reversed after longer preincubations, and paralleled the time course of endogenous phosphorylation-dephosphorylation of proteins observed under these conditions. The activation showed a critical requirement for Mg2+ ions and was dependent on ATP concentration. Similar activation was observed after preincubation of cerebral-cortical membranes with adenosine-5'-O-(3-thiophosphate) (ATP gamma S), but this activation was not reversed by prolonged preincubation times. The activation by ATP gamma S was potentiated severalfold by including synaptoplasm in the preincubation. Further experiments indicated that the activity of nucleoside diphosphokinase, which converts ATP gamma S to guanosine-5'-O-(3-thiophosphate) (GTP gamma S), could account for this potentiation. Preincubation of washed membranes for 5 min with 10 microM GTP and 10 mM MgCl2 also produced a 50% activation of adenylyl cyclase which withstood sedimentation and washing and was reversed by longer preincubations. Endogenous phosphorylation of specific protein components in the membranes during the preincubation was examined by including radioactively labeled nucleoside thiophosphates in the preincubation medium. Incorporation of 35S from [35S]ATP gamma S into a protein component with apparent Mr of 54,000 daltons ( 54K ) correlated significantly with the activation of adenylyl cyclase by ATP gamma S. Thiophosphorylation of the 54K protein was potentiated by addition of GDP to reactions carried out with [35S]ATP gamma S. Endogenous activity utilizing [gamma-32P]GTP as a phosphate donor also preferentially phosphorylated the 54K protein band. These results support previous suggestions that protein phosphorylation plays a role in the regulation of adenylyl cyclase activity. Among the numerous membrane-bound phosphoproteins in rat brain, we have identified a specific protein component with an apparent Mr of 54,000 daltons as the most likely candidate for involvement in this mode of regulation. This 54K protein, which is a principal substrate for a GTP-preferring protein kinase activity in brain membranes, can now be at the focus of investigations attempting to demonstrate a direct role for protein phosphorylation in adenylyl cyclase regulation.

Independence of blood pressure and locomotor hyperactivity in normotensive and genetically hypertensive rat

The spontaneously hypertensive rat (SHR) exhibits locomotor hyperactivity in comparison to its normotensive progenitor Wistar-Kyoto (WKY) strain. We asked whether the hyperactive behavior was a direct consequence of elevated blood pressure in the hypertensive rat. Three experimental protocols were used to chronically alter blood pressure. In the first protocol, a group of adult SHRs was given hydralazine (20 mg/kg/day) in their drinking water to lower blood pressure. These animals exhibited a significant decrease in blood pressure, but no change in locomotor activity. In the second protocol, young SHRs (4 weeks of age) were treated with the same dosage of hydralazine until 16 weeks of age. Blood pressure was significantly decreased in these animals with no change in locomotor activity. In the third protocol, normotensive WKY and Sprague-Dawley (SD) rats were made hypertensive with unilateral renal clips. The resulting increase in blood pressure in these animals did not alter locomotor activity. These results suggest that locomotor hyperactivity is an inherent property of the SHR and is independent of blood pressure.

Dissociation of genetic hyperactivity and hypertension in SHR

The Wistar Kyoto strain of spontaneously hypertensive rat (SHR) has been characterized as behaviorally hyperactive as well as hypertensive. The relationship between these two inbred traits remains uncertain, and their coexistence in the SHR has complicated studies of central nervous system mechanisms underlying the hypertensive process. A breeding program was initiated to examine the possible genetic linkage of these two traits which, if separable, would allow us to develop substrains of SHR that are hypertensive without being hyperactive, or hyperactive without being hypertensive. We crossed SHR males with Wistar Kyoto, normotensive (WKY) female rats and produced F1 hybrids which were then randomly inbred to produce an F2 population. When tested at 12 weeks of age, F2 rats exhibited the expected wide range of mean systolic blood pressures (BP), from 111 to 174 mm Hg, as determined using indirect tail plethysmography. The BP in the parental rats at the time of breeding (16 weeks) was 187 +/- 4.5 mm Hg (SHR males, n = 7) and 111 +/- 2.4 (WKY females, n = 7). Locomotor activity was determined in an automated activity cage in F1 and F2 rats at 12 weeks of age. These strains exhibited a wide range of phenotypic distribution of locomotor activity scores, and the mean scores were intermediary between those of SHR rats and WKY rats of the same age. Among individual rats of both the F1 and F2 hybrid strains, there was no correlation between the activity score and the level of the BP at 12 weeks of age. These findings indicated that the genes responsible for the hypertensive trait and those responsible for the hyperactivity trait were not tightly linked in the hybrid populations, suggesting that different genetic factors were involved in the transmission of each of these traits. Accordingly, it should be possible to separate the two traits by further selective, recombinant inbreeding procedures.

Changes in catecholamine neuronal uptake and receptor binding in the brains of spontaneously hypertensive rats (SHR)

In these studies we have characterized differences between spontaneously hypertensive rats (SHR) and normotensive Wistar/Kyoto (WKY) rats with respect to rates of neuronal uptake of norepinephrine (NE) and dopamine (DA), and beta-adrenergic receptor (dihydroalprenolol; [3H]DHA) binding in the central nervous system. We find that SHR have greater rates of NE uptake in the frontal cortex, cerebellum, hypothalamus and pons-medulla during early development, and that these changes are accounted for, at least in the cerebral cortex, by an increased Vmax of the NE uptake mechanism. In addition, we find a decrease in the Bmax for [3H]DHA binding, suggestive of down-regulation of beta-adrenergic receptors of this region. In contrast to the results for NE uptake, we have measured significant decreases in DA uptake in the frontal cortex of the SHR at several postnatal ages. Decreases in DA uptake were also observed in the striatum of SHR although these changes were found only in animals approximately 6 weeks of age. From these results we have suggested that NE neurons projecting to a number of brain regions have elevated functional activity, while more regionally selective decreases in dopaminergic functional activity are characteristic of the SHR. We have further proposed that these changes in catecholamine neurons of the central nervous system may play an important role in the development of both the hypertension and behavioral hyperactivity exhibited by these animals.

Protein phosphorylation mediates effects of isoproterenol on adenylate cyclase activity in rat cortical membranes

The effects of (-)-isoproterenol on adenylate cyclase activity were studied in rat cerebral cortical membranes prepared and assayed in the presence of calcium ions. In assays carried out in the presence of high Mg2+ concentrations (5-10 mM) and of Ca2+ in the micromolar range, addition of 1-100 micro M (-)-isoproterenol caused over 50% inhibition of adenylate cyclase activity. Since these conditions are optimal for supporting endogenous phosphorylative activity in synaptic membranes, we tested whether the observed effects are mediated by changes in the phosphorylation of specific proteins in these membranes. This was done by preincubation of lysed synaptosomes under phosphorylating conditions in the presence and absence of isoproterenol followed by extensive washes and analysis of cyclic AMP formation in resuspended membranes. Addition of (-)-isoproterenol to the preincubation resulted in a 30% decrease of adenylate cyclase activity in the reincubation. Inclusion of [gamma-32P]ATP in the preincubation and examination of the phosphorylation state of specific proteins in membranes entering the reincubation revealed that (-)-isoproterenol inhibited the phosphorylation of a specific protein band with apparent molecular weight of 47,000 (designated band F). These results support the hypothesis that alterations in membrane protein phosphorylation induced by neurotransmitters play a role in the regulation of adenylate cyclase activity.

Calcium-sensitive accumulation of norepinephrine in rat cerebral cortex

The accumulation of high and low concentrations of [3H]-norepinephrine has been examined in a crude synaptosomal preparation of rat cerebral cortex in the presence and absence of uptake1 inhibitors. When uptake1 was blocked, [3H]-norepinephrine accumulation exhibited very rapid initial rates. It was not inhibited by 10 mM normetanephrine, a potent inhibitor of peripheral uptake2, but it was inhibited by 10 mM metaraminol. This accumulation was markedly reduced when calcium ions were omitted from the incubation medium, and is named here 'calcium-sensitive accumulation' (CSA) to distinguish it functionally from the sodium-dependent, high affinity, uptake1 process. CSA may be localized in nerve endings since it was found predominantly i the synaptosomal fraction of homogenates subjected to density gradient centrifugation in sucrose or in Ficoll-in-sucrose. At high concentrations of [3H]l-norepinephrine (1.0 microM) and short incubation times, CSA accounted for most of the total accumulation of [3H]l-norepinephrine whereas uptake1 contributed only a small portion. Since extracellular concentrations of brain norepinephrine are thought to reach levels in excess of 1.0 microM, CSA may be a significant factor in noradrenergic neuronal transmission.

Acute stress and the brain norepinephrine uptake mechanism in the rat

The kinetic constants for norepinephrine uptake in cerebral cortical homogenates were determined in vitro immediately following an acute stress consisting of either forced immobilization, cold-wet exposure, combined cold-plus-restraint, swim stress, or electric footshock in the rat. The kinetic constants, apparent Km and Vmax, for uptake of 3H-l-norepinephrine were significantly increased only following 10 min swim at 22 degrees or following 5 min electric footshock. When severe hypothermia accompanied the stress, the findings suggested that a profound reduction in body temperature was associated with depressed responsiveness of brain noradrenergic mechanisms to stress including decreased uptake kinetic constants. In a series in which the duration of electric footshock was varied from 2 to 30 min, it was noted that the NE uptake kinetic constants were increased at 5 min, but were similar to paired controls at 2, 10 and 30 min following the onset of footshock. It was concluded that various acute stresses did not elicit a generalized response of the cortical NE uptake mechanism to stress in the rat. Furthermore, when uptake kinetic constants did change with stress, the values were often within the range of normal values seen in the rat.

Norepinephrine uptake into cerebral cortical synaptosomes after one fight or electroconvulsive shock

Membrane affinity for the neurotransmitter norepinephrine is rapidly but reversibly decreased in nerve terminals of the cerebral cortex by intense nervous stimulation. This should adaptively facilitate alerting during acute emergency and stress. The Michaelis constant (K(m)) for the high-affinity active uptake of norepinephrine into crude synaptosome-rich homogenates of the cerebral cortices of mice was increased 68 percent after 15 minutes of intense fighting and 110 percent 5 minutes after a single electroconvulsive shock. These changes were no longer evident 18 to 20 hours later.