Changes of salt intake and of (Na+K)-ATPase activity in brain after high dose treatment with deoxycorticosterone

Changes of hypothalamic and plasma vasopressin in rats with deoxycorticosterone-acetate induced salt appetite

Mineralocorticoids play a predominant role in development of salt appetite and hypertension. Since vasoactive peptides could mediate the central effects of mineralocorticoids, we evaluated changes of immunoreactive (IR) arginine vasopressin (AVP) in the paraventricular (PVN) and supraoptic (SON) hypothalamic nucleus during DOCA-induced salt appetite. In one model, rats having free access to water and 3% NaCl during 9 (prehypertensive stage) or 21 days (hypertensive stage) received DOCA (s.c., 10 mg/rat/in alternate days). A decrease in the IR cell area, number of IR cells and staining intensity was obtained in magnocellular PVN of rats treated during 9 days. After 21 days IR cell area and number of cells in the PVN also decreased, but staining intensity of remaining cells was normal. The same parameters were unchanged in the SON. In another model, animals treated with DOCA during 9 days had only access to 3% NaCl or water. The IR cell area in PVN and SON significantly increased in mineralocorticoid-treated and control animals, both drinking 3% NaCl. Staining intensity (PVN and SON) and number of IR cells (PVN) also augmented in DOCA-treated animals drinking salt respect of a group drinking water. Plasma AVP in rats treated with DOCA and offered salt and water, exhibited a 2-2.5 fold increase at the time of salt appetite induction. Plasma AVP was substantially higher in rats drinking salt only, while the highest levels were present in salt-drinking DOCA-treated rats. Thus, peptide depletion in the PVN may be due to increased release, because reduced levels of hypothalamic and posterior pituitary AVP were measured in this model. In rats drinking salt only the substantial increase of IR AVP in the PVN and SON, may be due to dehydration and hyperosmosis. Because DOCA-salt treated rats showed higher AVP levels in the PVN compared to untreated rats drinking salt only, it is possible that DOCA sensitized PVN cells to increase AVP production. The results suggest the vasopressinergic system could mediate some central functions of mineralocorticoids.

Increased expression of magnocellular vasopressin mRNA in rats with deoxycorticosterone-acetate induced salt appetite

The neuropeptides arginine vasopressin (AVP) and oxytocin (OT) have been implicated in the genesis of hypertension due to deoxycorticosterone acetate (DOCA)-salt treatment of uninephrectomized rats. In this work, we studied if DOCA treatment of intact rats in doses arousing a salt appetite (a prehypertensive state), modulated mRNA for AVP and OT in the hypothalamus. Male Sprague-Dawley rats were offered both tap water and 3% NaCl in separate bottles and received vehicle or subcutaneous injections of 10 mg DOCA on alternate days for 7 days (4 injections) or 17 days (9 injections). They developed a preference for 3% NaCl solutions 24-48 h after treatment. Brain slices from rats killed on the 8th or 18th day were exposed to 35S-labeled probes encoding prepro-AVP mRNA or OT mRNA, respectively. Expression of these mRNAs was measured in the magnocellular and parvocellular divisions of the paraventricular nucleus (PVN) and magnocellular cells of the supraoptic nucleus (SON). No changes were obtained in neuropeptide mRNA levels in the parvocellular division of the PVN between control and the two groups of DOCA-treated rats. However, DOCA-treated animals presented an increased number of grains per cell for AVP mRNA in the magnocellular division of the PVN and in magnocellular cells of the SON, as shown by group mean comparisons and frequency histograms. No changes were detected for OT mRNA. In a second series of studies, control or DOCA-treated rats were offered 3% NaCl or water as the only choice. Animals drinking 3% NaCl showed increased AVP and OT mRNA levels, whether they received DOCA or not. However, AVP mRNA levels in both nuclei were higher in DOCA-treated rats drinking 3% NaCl than in controls drinking salt solution. In comparison, control and DOCA-treated rats drinking water showed lower levels of AVP mRNA. OT mRNA levels in the SON remained unchanged in the same groups. The results suggest that in the magnocellular cells of the PVN and SON, increments in AVP mRNA are obtained following increments in salt intake produced by either mineralocorticoid treatment or exclusive salt drinking. In rats offered salt solution and water to drink, DOCA effects on AVP mRNA developed before changes occurred in serum sodium levels. Because combined DOCA + salt treatment induced a higher response in terms of AVP mRNA expression, we suggest that AVP could be a target of the central effects of the mineralocorticoid.

Regulation of gene expression by corticoid hormones in the brain and spinal cord

Glucocorticoids (GC) and mineralocorticoids (MC) have profound regulatory effects upon the central nervous system (CNS). Hormonal regulation affects several molecules essential to CNS function. First, evidences are presented that mRNA expression of the alpha3 and beta1-subunits of the Na,K-ATPase are increased by GC and physiological doses of MC in a region-dependent manner. Instead, high MC doses reduce the beta1 isoform and enzyme activity in amygdaloid and hypothalamic nuclei, an effect which may be related to MC control of salt appetite. The alpha3-subunit mRNA of the Na,K-ATPase is also stimulated by GC in motoneurons of the injured spinal cord, suggesting a role for the enzyme in GC neuroprotection. Second, we provide evidences for hormonal effects on the expression of mRNA for the neuropeptide arginine vasopressin (AVP). Our data show that GC inhibition of AVP mRNA levels in the paraventricular nucleus is sex-hormone dependent. This sexual dimorphism may explain sex differences in the hypothalamic-pituitary-adrenal axis function between female and male rats. Third, steroid effects on the astrocyte marker glial fibrillary acidic protein (GFAP) points to a complex regulatory mechanism. In an animal model of neurodegeneration (the Wobbler mouse) showing pronounced astrogliosis of the spinal cord, in vivo GC treatment down-regulated GFAP immunoreactivity, whereas the membrane-active steroid antioxidant U-74389F up-regulated this protein. It is likely that variations in GFAP protein expression affect spinal cord neurodegeneration in Wobbler mice. Fourth, an interaction between neurotrophins and GC is shown in the injured rat spinal cord. In this model, intensive GC treatment increases immunoreactive low affinity nerve growth factor (NGF) receptor in motoneuron processes. Because GC also increases immunoreactive NGF, this mechanism would support trophism and regeneration in damaged tissues. In conclusion, evidences show that some molecules regulated by adrenal steroids in neurons and glial cells are not only involved in physiological control, but additionally, may play important roles in neuropathology.

Aldosterone up-regulates mRNA for the alpha3 and beta1 isoforms of (Na,K)-ATPase in several brain regions from adrenalectomized rats

In physiological doses, mineralocorticoids (MC) normalize the high salt intake developed after adrenalectomy. We have studied whether this effect of MC is accompanied by changes in the mRNA of neuronal alpha3 and beta1 subunits of the (Na,K)-ATPase because this enzyme could by a mediator of MC action in target cells. We employed [35S]oligonucleotide probes for the mentioned subunits hybridized to brain sections from adrenalectomized rats and adrenalectomized rats receiving aldosterone (ALDO) during 4 days. Using t-test statistics to measure differences in mean levels of grain density, and the Kolmogorov-Smirnov non-parametric test applied to frequency histograms, we showed that ALDO increased the alpha3 subunit mRNA in the septum medialis, preoptic area medialis, caudate-putamen, periventricular gray substance, amygdala lateralis, hippocampal subfields CA1 to CA4 and the gyrus dentatus. Significant increases for the beta1 subunit mRNA were found in periventricular gray substance, the CA1-CA4 hippocampal subfields and gyrus dentatus. Therefore, the salt-suppression effect of MC was accompanied by coordinate increases in (Na,K)-ATPase alpha3 and beta1 subunit mRNA in the hippocampus, gyrus dentatus and periventricular gray substance, whereas in other regions the stimulatory effect was exclusive of the alpha3 subunit mRNA only. The results suggest that the enzyme could be a target of ALDO action not only in areas related to salt appetite control (amygdala, preoptic area) but also in brain regions subserving other functions of the MC.

Neurobiological correlates of masculine sexual behavior

The experimental analysis of the neuroendocrine interactions regulating sexual behavior has traditionally relied on studying the effects of CNS lesions and pharmacological treatments with hormones or drugs purportedly acting through specific neurotransmitter systems. New methodological developments have allowed the assessment of several indices of neural function in experimental animals, particularly the rat, as they relate to behavioral changes. In the field of sexual behavior, ex vivo analyses have been used to measure markers of energy metabolism, such as 2-deoxyglucose uptake and Na,K-ATPase activity, the tissue content of neurotransmitters and metabolites, the levels of steroid receptors and neurosteroids, and immediate-early gene expression products in different areas of the CNS. In vivo studies have monitored brain electrical activity and temperature, as well as the extracellular levels of neurotransmitters and metabolites by cerebrospinal fluid sampling, push-pull perfusion and, especially, electrochemical recordings and microdialysis, in the course of mating and exposure to various relevant stimuli. The findings with the different methodologies are generally consistent and agree with those of previous surgical and pharmacological manipulations. They provide data on temporal relationships between neurobiological and behavioral events and suggest new interpretations for different aspects of the male copulatory pattern.

The ingestion of calcium in multiparous and virgin female rats

The present experiments demonstrate that multiparous females ingest more calcium that virgin females. In two experiments, we demonstrated that multiparous females ingested more calcium than virgin females, and both ingested larger amounts than males. The biological basis for this enhanced avidity for calcium lie in the greater needs for calcium during reproduction.

Glucocorticoid regulation of mRNA encoding (Na+K) ATPase alpha 3 and beta 1 subunits in rat brain measured by in situ hybridization

The effect of glucocorticoids on (Na+K)ATPase mRNA synthesis was studied in 19 brain areas of adrenalectomized (ADX) rats untreated or receiving dexamethasone (DEX). For in situ hybridization, we employed a [35S]oligonucleotide probe for the alpha 3-subunit isoform, and a [3H]cDNA coding for the beta 1-subunit of the enzyme. Mean levels of grain density for the alpha 3 subunit mRNA of DEX-treated rats were significantly higher by a 't' test in medial septum, amygdala lateralis (AL) and medialis (AME), gyrus dentatus, CA4 hippocampal area, substantia nigra and periventricular gray, compared to untreated rats. For the beta 1-subunit, mean levels after DEX were significantly higher in AL and lateral preoptic area. In addition, the Kolmogorov-Smirnov test applied to frequency histograms of neuronal densities indicated a coordinate increase in alpha 3 and beta 1-subunit mRNA expression for the CA2 subfield and preoptic area medialis (POA MED). We conclude that (1) glucocorticoids are positive modulators of (Na+K)ATPase mRNA; (2) analysis of frequency histograms suggests that glucocorticoids promote in a few regions (AL, POA MED, CA2 subfield) a coordinate increase in the biosynthesis of the alpha 3 and beta 1-subunit mRNA. In 11 other areas stimulation occurs for one subunit mRNA only, whereas 5 areas were insensitive to glucocorticoid effects on this enzyme.

Effects of deoxycorticosterone acetate (DOCA) and aldosterone on Sar1-angiotensin II binding and angiotensin-converting enzyme binding sites in brain

1. It is known that regulation of salt appetite is a complex behavior controlled in the brain by interaction of mineralocorticoids (MC) and angiotensin II (ANGII). To investigate the effects of MC on ANGII receptors and ANGII synthesis, we have studied two models of salt appetite control. 2. In the first model, doses of DOCA sufficient to induce salt appetite of intact rats were given. In the second one, we studied the effects of aldosterone (ALDO) in doses sufficient to suppress salt appetite developed by prior adrenalectomy (ADX). 3. Binding to ANGII receptors was determined in brain sections incubated with 3 nM [125I]Sar1 ANGII, exposed to [3H]Hyperfilm with an optical density of autoradiograms measured by computerized densitometry. Sar1-ANGII binding was increased by DOCA treatment in the median preoptic nucleus (MnPO) and subfornical organ (SFO) but not in the paraventricular nucleus (PVN) in comparison to vehicle-treated rats. ALDO treatment was without effect on the MnPO but increased ANGII binding in the SFO and PVN. Neither hormone affected binding in the median eminence or anterior pituitary (AP). 4. In contrast to effects on Sar1-ANGII binding in selected areas, [125I]351A binding to angiotensin-converting enzyme (ACE) was unchanged by DOCA or ALDO administration in the SFO, caudate putamen, AP, or posterior pituitary. 5. These findings suggest that MC modulation of the renin-angiotensin system is exerted at the central, and not at the pituitary level. ANGII receptors were modulated in a dose- and region-specific manner: while DOCA may promote their actions upon the MnPO and SFO, ALDO actions may occur at the PVN and SFO. This mechanism may not require increased generation of ANGII in the brain or pituitary.

Regulation of flunitrazepam binding in the dorsal horn of the spinal cord by adrenalectomy and corticosteroids

Adrenal corticosteroids and adrenalectomy (ADX) have opposing effects on benzodiazepine binding sites in brain regions. These treatments were employed to study [3H]flunitrazepam (FLU) binding in regions punched out from the rat spinal cord. We found that binding was higher in dorsal horn than in ventral horn, and minimal in white matter. Clonazepam and RO 15-1788 largely displaced [3H]FLU binding, whereas RO 5-4864 was weakly active. Four days post-ADX, binding increased exclusively in the dorsal horn, and this effect was reversed by administration of corticosterone (CORT), but not dexamethasone (DEX) or aldosterone (ALDO) given over 4 days. When endogenous CORT was increased by administration of cold stress to adrenal-intact rats, reduced benzodiazepine (BDZ) binding was also observed in the dorsal horn. When added in vitro, only ALDO and not CORT or DEX, inhibited [3H]FLU binding. It is suggested that steroids with affinity for the type I corticosteroid receptor (CORT, ALDO) decrease [3H]FLU binding to a neural-type BDZ receptor in the dorsal horn. Reduction of the inhibitory BDZ system may be physiologically important, and can partly explain the enhancement of excitatory synaptic transmission produced by corticosteroids at the level of the spinal cord.

Transformation and nuclear translocation of brain type L corticosteroid receptors complexed with the mineralocorticoid antagonist ZK 91587, aldosterone or dexamethasone

Type I corticosteroid receptors were determined in cytosol from hippocampus (HIPPO) and amygdala (AMYG), using [3H]aldosterone (ALDO), [3H]dexamethasone (DEX) or the mineralocorticoid antagonist [3H]ZK 91587 as ligands. Incubations with the first two compounds also contained the pure glucocorticoid RU 28362 to block type II receptors. Binding of the three ligands was comparable in cytosol from HIPPO and it was slightly higher for [3H]DEX in AMYG. However, after heat-induced receptor transformation, binding to DNA-cellulose was observed for [3H]ALDO-receptor complex obtained from HIPPO or AMYG, whereas it was negligible for [3H]ZK 91587. Receptors charged with [3H]DEX or [3H]ALDO showed similar retention on DNA-cellulose columns in the case of the AMYG, while binding to the polynucleotide was higher for [3H]ALDO in the HIPPO. Finally, only [3H]ALDO was taken up to a significant extent in purified cell nuclei prepared from slices of HIPPO and AMYG previously incubated with the three ligands. It is concluded that binding of a natural agonist steroid may be a prerequisite for type I receptor transformation and translocation from the cytoplasm into the nuclear fraction. DEX binding to type I receptors resembles a partial agonist with antagonist properties, whereas antagonists such as ZK 91587 are bound and retained in cytoplasm, without further translocation.

Effects of deoxycorticosterone treatment on beta-subunit mRNA for (Na + K)ATPase in brain regions determined by in situ hybridization

1. We have used in situ hybridization techniques to determine the mRNA for (Na + K)ATPase in 20 brain regions from control rats and rats treated with high doses of deoxycorticosterone (DOC). 2. DOC-treated rats developed a salt appetite following the second hormone administration on alternate days and were used after the fourth DOC administration. 3. DOC treatment did not change the number of silver grains/cell deposited in cells from Ca1, CA2, CA3, and CA4 hippocampal subfields, dentate gyrus, cerebral cortex, medial preoptic area (POA), substantia nigra, and periventricular gray matter. 4. Nonsignificant reductions were detected in lateral POA, medial and lateral septum, caudate-putamen, and three amygdaloid nuclei (cortical, basolateral, and central) from DOC-treated rats. 5. Significant reductions were obtained, after DOC administration, in arcuate and ventromedial hypothalamic nuclei and medial and lateral amygdala. 6. The results suggested that regulation of the beta-subunit mRNA of (Na + K)-ATPase may be related to the central actions of mineralocorticoids in the control of salt intake.

Glucocorticoid receptors and enzyme induction in the spinal cord of rats: effects of acute transection

The spinal cord is a glucocorticoid-responsive tissue, as demonstrated by hormonal effects on enzyme induction and by the presence of type II and type I glucocorticoid receptors in cytoplasmic extracts of this CNS region. Using microdissection techniques, we have found in the present investigation that glucocorticoid type II receptors are the most abundant class detected in gray (ventral and dorsal horns) and white (lateral funiculus) matter and that the distribution of type II sites among these regions was quantitatively similar. Type I sites were also quantified, with a slight prevalence in gray matter as opposed to white matter. Furthermore, stimulation of an inducible enzyme, ornithine decarboxylase (ODC), was found in ventral horn and lateral funiculus but not in dorsal horn after administration of dexamethasone (DEX), a type II receptor ligand. We also found that surgical transection of the spinal cord, while markedly increasing ODC activity per se, did not prevent the stimulatory effect of DEX administration on ODC activity measured in the lumbar enlargement of the spinal cord located below the surgical lesion. Taken together, the results suggest a direct effect of glucocorticoids on ODC activity in the spinal cord of rats, probably mediated by glucocorticoid receptors (type II) found in target cells of the ventral horn and lateral funiculus. The results also indicate that glucocorticoid receptors of the dorsal horn were not involved in ODC induction, and a function for these receptors awaits the results of further experimentation.

Properties and distribution of binding sites for the mineralocorticoid receptor antagonist [3H]ZK 91587 in brain

We have studied the binding of the synthetic antimineralocorticoid [3H]ZK 91587 to soluble receptors in brain of adrenalectomized rats. It was observed that [3H]ZK 91587 labeled a single receptor class with high affinity (Kd 1.3 nM) and low capacity (51.1 fmol/mg prot.) in cytosol of hippocampus (HIPPO). The ligand was efficiently displaced in vitro from the receptor by aldosterone (IC50 2.0 nM) and corticosterone (2.3), while dexamethasone showed less potency (IC50 5.1 nM) and the pure antiglucocorticoid RU 28362 competed weakly (161 nM). Furthermore, there was a widespread distribution of binding sites all over the brain for this compound, but with CA1 and CA3 regions of HIPPO, some amygdaloid nuclei and lateral septum containing most of the binding sites, as revealed by binding assays employing 16 different microdissected brain regions. Finally, the receptor labeled with [3H]ZK 91587 was readily displaced by administration of aldosterone in vivo in physiological amounts, from 5 whole brain regions examined, but preferentially from preoptic area, amygdala and HIPPO. It is concluded that [3H]ZK 91587 is a useful ligand for further studies on putative mineralocorticoid responsive cells in brain, due to its high affinity, stability and lack of cross reactivity with glucocorticoid receptors. Its brain distribution is similar to that previously obtained using [3H]aldosterone in the presence of RU 28362 to block ligand binding to the glucocorticoid receptor.