The Hippocampus: A Site for Modulatory Interactions Between Steroid Hormones, Neurotransmitters and Neuropeptides. In: Müller EE, Macleod RM, editors. Neuroendocrine Perspectives. New York: Springer; 1990. pp. 93-131. [DOI: 10.1007/978-1-4612-3446-3_4]

Repeated administration of dexamethasone increases phosphoinositide-specific phospholipase C activity and mRNA and protein expression of the phospholipase C beta 1 isozyme in rat brain

Altered hypothalamic-pituitary-adrenal (HPA) function has been shown to be associated with changes in mood and behavior. The enzyme phosphoinositide-specific phospholipase C (PI-PLC), an important component of the PI signal transduction system, plays a major role in mediating various physiological functions. In the present study, we investigated the effects of a single dose and of repeated administration (0.5 or 1.0 mg/kg for 10 days) of dexamethasone (DEX), a synthetic glucocorticoid, on PI-PLC activity and on expression of PLC isozymes (beta1, delta1, and gamma1) in rat brain. Repeated administration of DEX (1.0 mg/kg) caused a significant increase in PI-PLC activity and in protein expression of the PLC beta1 isozyme in both membrane and cytosol fractions of cortex and hippocampus; however, the repeated administration of a smaller dose of DEX (0.5 mg/kg) caused these changes only in hippocampus but not in cortex. The increase in PLC beta1 protein was associated with an increase in its mRNA level, as measured by competitive RT-PCR. A single administration of DEX (0.5 or 1.0 mg/kg) to rats had no significant effects on PI-PLC activity or on the protein expression of PLC isozymes. These results suggest that DEX up-regulates PI-PLC in rat brain, which presumably is due to a selective increase in expression of the PLC beta1 isozyme, and that these changes in PI-PLC may be related to HPA axis-mediated changes in mood and behavior.

Effects of controllable and uncontrollable stresses on the receptor binding of dexamethasone in the hypophysis and hippocampus of rats with different behavior strategies

The effects of controllable and uncontrollable stress on the receptor binding of dexamethasone in the hypophysis and hippocampus were studied in KHA and KLA rats, lines selected for the ability to development of active escape. Presentation of the controllable stimulus led to a significant reduction in receptor binding of dexamethasone in the hippocampus with significant changes in the plasma corticosterone concentration and receptor binding in the hypophysis. KLA rats were sensitive both to the controllable and the uncontrollable stresses, with increases in plasma corticosterone and receptor binding of dexamethasone in the hypophysis. It is concluded that receptor binding of dexamethasone in the hippocampus and hypophysis depend not only on the behavioral strategy of the animal, but also on the possibility of controlling the situation.

Differential effects of immunologic challenge on self-stimulation from the nucleus accumbens and the substantia nigra

Paralleling the effects of uncontrollable stressors, systemic administration of sheep red blood cells (SRBC) provokes brain neurotransmitter alterations, including DA variations within mesocorticolimbic regions, coinciding with or slightly preceding the peak immune response. Inasmuch as stressors disrupt responding for brain stimulation from the nucleus accumbens, possibly reflecting the anhedonic consequences of stressors, the present investigation assessed whether antigenic challenge would also influence responding for brain stimulation. Sheep red blood cell administration was found to reduce responding for brain stimulation from the nucleus accumbens, without affecting performance from the substantia nigra. The alterations of self-stimulation from the nucleus accumbens occurred at times that approximated the peak immune response. These data suggest that antigenic challenge may induce anhedonic-like effects that may be secondary to central neurochemical alterations engendered by the treatment. The possibility is also entertained that antigenic challenge may be interpreted as a stressor and contribute to alterations of affect.

Corticosteroid regulation of gene expression and binding characteristics of vasopressin receptors in the rat brain

Arginine-vasopressin (AVP) plays significant roles in neuroendocrine and autonomic regulation, and in processing of cognitive information. Its synthesis and secretion are subject to control by circulating glucocorticoids. The lateral septum and subdivisions of the hippocampus are innervated by AVP-ergic fibres and, together with AVP-producing neurons in the hypothalamic paraventricular nucleus, are major neural targets of glucocorticoid negative feedback. In this study, we investigated the effects of chronic adrenalectomy (ADX) and subsequent treatment with supraphysiological doses of corticosterone (B) on the gene expression of AVP receptors of the V1a subtype in the septum, hippocampus and hypothalamic arcuate (ARC) nucleus using semiquantitative in situ hybridization histochemistry. Adrenalectomy did not alter AVP receptor expression in any of the structures studied. Supplementation with B significantly decreased AVP receptor expression in the lateral septum and hippocampus, whereas receptor mRNA levels in the ARC were indistinguishable from those measured in controls. In a complementary study, we investigated the binding characteristics of V1 AVP receptors in membrane preparations from the hippocampus. Adrenalectomy significantly decreased the number of AVP binding sites, and chronic corticosteroid treatment was associated with a further suppression of AVP receptor concentrations in this structure. These results indicate that the gene transcription of V1a AVP receptors in the brain is regulated by circulating glucocorticoids in a site-specific fashion that largely reflects the corticosteroid sensitivity of the corresponding structure.(ABSTRACT TRUNCATED AT 250 WORDS)

Gene products of corticosteroid action in hippocampus

We used two methods to examine altered patterns of gene expression in rat hippocampus in response to administered glucocorticoids: analysis of RNA in vitro translation products on 2-d gels and cloning of cDNAs from a rat hippocampal library by differential hybridization (+/- CORT). We determined that two of the CORT-responsive cDNA clones encoded the 35- and 50-kd RNA translation products and identified them as GPDH and GFAP, respectively, by sequence analysis. Cloned mRNAs that increased and decreased in response to CORT were determined to be under positive and negative regulation by glucocorticoids in intact rats. Despite their similarities in glucocorticoid response characteristics, we found three subsets of hippocampal mRNA responses to CORT and shaking stress which differ in temporal and level-dependent aspects of CORT regulation. In addition, GPDH gene expression represents a glucocorticoid-dependent stress response which is rapidly increased in a dose- and stressor-dependent manner. It is a candidate for a sensitive indicator of stress responsiveness in the brain as a function of neuroendocrine activity. Mechanisms of adaptation to stress in the brain are likely to involve responses that are both mediated by glucocorticoids and opposed by them. GFAP and TGF-beta 1 mRNA responses may be examples of the latter, since they are decreased in response to glucocorticoids, are under negative regulation by glucocorticoids in intact rats, and are increased in response to brain injury and disease and during aging. If these astrocytic and microglial responses are involved in cellular defense mechanisms in the brain, then their regulation by glucocorticoids would be important in maintaining and restoring cellular homeostasis in physiological and pathophysiological states. Future studies using these sensitive probes for glucocorticoid-regulated gene expression may identify new mechanisms by which the brain coordinates acute and chronic responses to stress and disease.

Vasopressin-induced neurotrophism in cultured hippocampal neurons via V1 receptor activation

Structural enhancement of nerve cell morphology has been postulated to be an integral step in the cellular process leading to information storage in the nervous system. To investigate this postulate, we determined whether vasopressin (AVP), a neural peptide that can enhance memory function, would enhance the cytoarchitectural features of hippocampal neurons in culture. Results of these studies demonstrated that in the presence of serum, vasopressin (1 microM), induced a significant increase in the number of neurites, in neuritic length, and in neurite diameter following 48 h of exposure. Morphological complexity was also enhanced following vasopressin exposure as indicated by a significant increase in the number of filopodia/branches, in the sum of branch lengths, and in the number of branch bifurcation points. The number of microspikes decorating neuritic branches was also significantly increased following vasopressin exposure. To determine whether the neurotrophic effect of vasopressin was dependent upon factors present in serum, hippocampal nerve cells were cultured in serum-free media and exposed to 100-1000 nM AVP. Results of these studies demonstrated that in the absence of serum, AVP induced significant enhancement of hippocampal nerve cell growth and that the minimally effective concentration was reduced from 1 microM, as required in the presence serum, to 100 nM. In addition, the time required for a significant increase in nerve cell growth to become apparent decreased from 48 to 24 h. These results demonstrate that AVP-induced neurotrophism is not dependent upon unidentified factors in serum. AVP-induced neurotrophism was found to be mediated by V1 receptor activation. Significant enhancement of nerve cell growth occurred following exposure to V1 receptor agonist (100-1000 nM), whereas exposure to V2 receptor agonist (100-1000 nM) did not increase any of the morphological parameters measured. Considered together, these data indicate that vasopressin can exert a significant neurotrophic effect upon hippocampal nerve cells in culture. Moreover, AVP-induced neurotrophism is a direct effect and not dependent upon unidentified factors present in serum. Enhancement of hippocampal nerve cell growth occurred in the presence of a specific V1 receptor agonist and not following exposure to a V2 agonist, suggesting that activation of the phosphatidyl inositol pathway via V1 receptor activation mediates AVP-induced neurotrophism. Results of these studies are discussed with respect to their implications for understanding vasopressin involvement during neural development and induction of cytoarchitectural modifications associated with memory formation.

Estradiol increases glucocorticoid binding and glucocorticoid induction of ornithine decarboxylase in the rat spinal cord

Previous results demonstrated that estradiol (E2) treatment of ovariectomized-adrenalectomized (OVX-ADX) rats increased glucocorticoid (GC) binding in brain regions. The experimental protocol was extended to the spinal cord, a GC target tissue in which ornithine decarboxylase (ODC) is markedly induced by GC treatment. First, we measured GC binding to type I and type II receptors in ventral horn, dorsal horn and lateral funiculus of OVX-ADX rats treated during 4 days with E2 or vehicle. In E2-treated rats, type II receptors increased solely in dorsal horn, whereas type I sites remained unchanged. Second, in a group of OVX-ADX rats receiving dexamethasone (DEX), pretreatment with E2 superinduced ODC in ventral horn and lateral funiculus, but not in dorsal horn. Third, we found that the dorsal horn was relatively enriched in E2 receptors compared to other areas. Therefore, E2 stimulation of GC binding to type II sites may be mediated through E2 receptors localized in the dorsal horn. We suggest that combined treatment with E2 and DEX employs a transsynaptic mechanism for ODC induction at the ventral horn and lateral funiculus, with hormonal interaction taking place at the dorsal horn level.

Glucocorticoid type II receptors of the spinal cord show lower affinity than hippocampal type II receptors: binding parameters obtained with different experimental protocols

We have used three experimental protocols to determine binding parameters for type I and type II glucocorticoid receptors in the spinal cord and hippocampus (HIPPO) from adrenalectomized rats. In protocol A, 0.5-20 nM [3H]dexamethasone (DEX) was incubated plus or minus a 1000-fold excess of unlabeled DEX, assuming binding to a two-site model. In protocol B, [3H]DEX competed with a single concentration of RU 28362 (500 nM), whereas in protocol C, we used a concentration of RU 28362 which varied in parallel to that of [3H]DEX, such as 500 x. Results of protocols A and C were qualitatively similar, in that: (1) Bmax for type I receptors favored the HIPPO, while the content of type II sites was comparable in the two tissues; (2) Kd was consistently lower for type I than for type II sites in both tissues; and (3) type II receptors from the spinal cord showed lower affinity than their homologous sites from HIPPO. This last result was also obtained when using protocol B. In contrast, protocol B yielded binding data indicating that type II sites were of similar or higher affinity than type I sites. Computer simulation of the binding protocols demonstrated that protocols A and C were the most theoretically reliable for estimating the Kd and Bmax of type I sites, and the predicted error was smaller for protocol C, in comparison with protocol B. We suggest that the noted differences in the Kd of type II receptors between the spinal cord and HIPPO could account for a difference in sensitivity of the two systems in the physiological adrenal hormone range.

Diurnal differences and adrenal involvement in calmodulin stimulation of hippocampal adenylate cyclase activity

Abstract Calciam/calmodulin-dependent processes are altered by manipulations of the hypothalamic-pituitary-adrenal axis, and are associated with changes in synaptic efficacy in the hippocampus, such as long-term potentiation. Recent evidence indicates that there are diurnal variations in the threshold for long-term potentiation, as well as diverse effects of the adrenals and of adrenal steroids on electrical activity related to long-term potentiation. In order to probe possible mechanisms underlying these observations, we investigated the effects of the diurnal cycle, as well as adrenalectomy (ADX) and adrenal demedullation on adenylate cyclase activity. In hippocampal, but not cortical, membranes the adenylate cyclase response to calmodulin was higher during the beginning of the dark phase of the cycle, when endogenous corticosterone levels are high. Basal and forskolin-stimulated adenylate cyclase activity did not exhibit diurnal variation in either brain region. ADX (6 and 14 days) depressed the adenylate cyclase response to calmodulin in hippocampal membranes, and abolished the diurnal difference. ADX had smaller effects on this response in cortical membranes. ADX also attenuated basal and forskolin-stimulated adenylate cyclase activity, but these changes were less striking than effects on calmodulin-stimulated activity. Demedullation (14 days), generating corticosterone levels in the low physiological range, mirrored the effects of ADX on hippocampal adenylate cyclase activity. Corticosterone (20 to 25 mug/ml in the drinking water) did not consistently prevent ADX effects on adenylate cyclase activity. These results demonstrate that adrenal effects on adenylate case activity are regionally specific within the brain, and they suggest that other adrenal secretions besides glucocorticoids may be involved in the feedback of the diurnal rhythm on the hippocampus. Taken together with our recent finding that chronic stress or corticosterone injection selectively attenuated the adenylate cyclase response to calmodulin in cortical, but not hippocampal membranes our findings provide further support for a role of the pituitary-adrenal axis in modulating neural calmodulin-dependent adenylate cyclase activity.

Effect of chronic adrenalectomy on neuron loss and distribution of sulfated glycoprotein-2 in the dentate gyrus of prepubertal rats

This study extends the unexpected finding of Sloviter et al. (Science, 1989, 243: 535-538) that adrenalectomy (ADX) of young rats casues a loss of granule neurons in the dentate gyrus. In particular, we determined how the vulnerability of dentate granule neurons to the cytocidal effect of ADX is related to the completeness of the ADX and whether sulfated glycoprotein-2, a putative component of programmed cell death, is associated with the death of granule neurons after ADX. We report that 4 months after bilateral ADX of young (150-175 g) rats only ADX rats that had attenuated weight gain and less than 2 ng/ml of serum corticosterone lost granule neurons; whereas as little as 15 ng/ml of serum corticosterone was sufficient to protect granule neurons from cell death. In addition, by immunocytochemistry, SGP-2 was distributed as punctate deposits throughout the molecular layer of the dentate gyrus and in glial cells juxtaposed to surviving neurons in the dentate of ADX rats with a granule cell loss. However, immunoreactivity for SGP-2 was not found in granule neurons that exhibited morphological signs of cellular generation after ADX.