Béla Bohus

Effect of oxytocin and vasopressin on memory consolidation: sites of action and catecholaminergic correlates after local microinjection into limbic-midbrain structures

The effects of local postlearning microinjections of arginine-vasopressin (AVP) and oxytocin (OXT) on one-trial learning passive avoidance behavior and the influence of AVP on alpha-MPT-induced disappearance of norepinephrine (NE) and dopamine (DA) in discrete brain regions have been studied in the rat. OXT injected bilaterally in the hippocampal dentate gyrus (25-25 pg) or in the midbrain dorsal raphe nucleus (50 pg) significantly attenuated passive avoidance behavior. Facilitation of passive avoidance behavior was observed when the peptide was injected into the dorsal septal nucleus. AVP facilitated passive avoidance behavior when administered into the hippocampal dentate gyrus, dorsal raphe nucleus or dorsal septal nucleus. Injection of either neuropeptides into the central amygdaloid nucleus appeared to be ineffective. One week after the behavioral experiments a repeated injection of AVP into the hippocampal dentate gyrus increased the disappearance of NE in the dentate gyrus and in the nucleus ruber. An injection into the dorsal septal nuclei decreased the NE disappearance in the dorsal septal nucleus itself and increased it in the nucleus ruber. Injection in the dorsal raphe nucleus led to an increase in the disappearance of DA in the locus coeruleus and in the nucleus ruber. It is concluded that memory consolidation can be oppositely influenced by local application of minute amounts of either OXT or AVP into certain limbic-midbrain structures, suggesting an involvement of these brain regions in the memory effects of these peptides. Modulation of catecholamine turnover in specific brain areas after AVP administration may be related to this behavioral effect.

Neuroleptic activity of the neuropeptide β-LPH62–77 ([Des-Tyr1]γ-endorphin; DTγE)

In contrast to β-endorphin, α-endorphin, β-LPH61–69 and Met-enkephalin which delay extinction of pole-jumping avoidance behavior (De Wied et al., 1978), γ-endorphin given either subcutaneously (30 ng/rat) or intraventricularly (0.3 ng/rat) facilitated extinction. Removal of the N-terminal amino acid residue tyrosine — yielding the neuropeptide [Des-Tyr1]γ-endorphin (DTγE) — which destroys the opiate-like activity as determined on the electrically driven guinea pig ileum, potentiated the facilitating effect of γ-endorphin on pole-jumping avoidance behavior. Observations on passive avoidance behavior gave essentially the same results. Whereas α-endorphin facilitated this behavior. DTγE attenuated passive avoidance behavior. Amounts of γ-endorphin and DTγE which were highly active on extinction of pole-jumping avoidance behavior (0.3 μg s.c. per rat) were without effect on gross behavior in an open field. Much higher amounts (10–50 μg s.c. per rat) also failed to affect the rate of ambulation in an open field. In relatively high doses (20 μg i.v.t. or 50 μg s.c. per rat), γ-endorphin and in particular DTγE were positive in the various “grip tests”. Haloperidol given s.c. (0.03–0.1 μg/rat) facilitated extinction of pole-jumping avoidance behavior and attenuated passive avoidance behavior. The same amounts decreased ambulation in an open field. In higher doses haloperidol was active in the “grip tests” but in addition caused severe immobility, ptosis and extension of the lower limbs. Intraventricularly administered morphine or β-endorphin induced wide open eyes, exophthalmus, rigidity and reduced reflexes, in contrast to γ-endorphin and DTγE which did not produce such effects. These results are interpreted to indicate that DTγE or a closely related peptide is an endogenous neuroleptic. It may be that a reduced availability as a result of an inborn error in the generation of DTγE is an etiological factor in psychopathological states for which neuroleptic drugs are beneficial.

The temporal dynamics of the stress response.

This paper summarises the available evidence that failure of defense mechanisms in (semi)-natural social groups of animals may lead to serious forms of stress pathology. Hence the study of social stress may provide animal models with a high face validity. However, most of the animal models of human stress-disorders have concentrated on the consequences of chronic exposure to stressors. The present paper considers recent data, indicating that a single experience with a major stressor in the form of social defeat may have long-term consequences ranging from hours to days and weeks. It seems that the experience of a major stressor sensitizes the animal to subsequent stressors. The consequences of these long-term temporal dynamics of the stress response to the development of stress-related disorders and stress-vulnerability are discussed.

Neuroendocrine states and behavioral and physiological stress responses.

Publisher Summary This chapter presents a novel, behavioral physiological stress concept that originates from the classical view that stress is a response. This new concept is extended to environment, behavior, and physiology, and it incorporates the novel neuroendocrine views including the neuropeptide concept. Stress is viewed as a general biological and usually functional response to environmental and bodily demands. A stress depends on interactions among environment, individual characteristics and the properties of stressors, stress, and the physiological systems, and also among the nervous system, peripheral organ systems, and the neuroendocrine system. To adapt to the altering social and physical environmental demands, man and other animals require a chain of behavioral, neuroendocrine, and autonomic physiological and metabolic responses to maintain bodily and mental homeostasis. The neuroendocrine state of the brain is given a central position in determining the state of health or disease of mind and body.

Differences in basal and stress-induced HPA regulation of wild house mice selected for high and low aggression ☆

Male wild house mice, selected for short (SAL) and long (LAL) attack latency, show distinctly different behavioral strategies in coping with environmental challenges. In this study, we tested the hypothesis that this difference in coping style is associated with a differential stress responsiveness of the hypothalamic-pituitary-adrenal (HPA) system. SAL rather than LAL mice showed a clear fluctuation in circulating corticosterone concentrations around the circadian peak with significantly higher levels in the late light phase. LAL mice showed lower basal ACTH levels and higher thymic and spleen weights compared to SAL. Under basal conditions, glucocorticoid receptor (GR) and mineralocorticoid receptor (MR) mRNA in the hippocampus and corticotropin-releasing hormone (CRH) mRNA in the paraventricular nucleus of the hypothalamus were not different between the two lines. Forced swimming for 5 min induced high immobility behavior in LAL mice which was associated with an enhanced and prolonged corticosterone response as compared to SAL, while absolute ACTH levels did not differ. In addition, LAL mice showed an increase in hippocampal MR mRNA (but not GR) and hypothalamic CRH mRNA at 24 h after forced swimming. In conclusion, a genetic trait in coping style of wild house mice is associated with an idiosyncratic pattern of HPA activity, and greater responsiveness of physiological and molecular stress markers in LAL mice. In view of the profound differences in behavioral traits and stress system reactivity, these mouse lines genetically selected for attack latency present an interesting model for studying the mechanism underlying individual variation in susceptibility to stress-related psychopathology.

Dose-dependent suppression of adrenocortical activity with metyrapone: Effects on emotion and memory

Different levels of circulating corticosterone are considered to produce different emotional states and effects on learning and memory. The purpose of the present study was to use different doses of the 11-beta-hydroxylase inhibitor metyrapone to produce dose-dependent inhibition of the synthesis of corticosterone and examine the consequences of that on several cognitive and emotional parameters. Systemic (SC) injections of metyrapone (25 or 50 mg/kg) dose-dependently suppressed increases in plasma concentrations of corticosterone induced by spatial training in a water maze, but did not affect plasma corticosterone levels in non-stressed rats. Treatment with the higher and lower dose of metyrapone also differentially affected behavioral measures of emotion and memory. Administration of 50 mg/kg, but not 25 mg/kg, of metyrapone impaired acquisition performance in the spatial water maze task. Both doses of metyrapone impaired retention. The impairment in retention was attenuated by dexamethasone (0.3 mg/kg) given systemically immediately after training, but not by corticosterone (0.3 mg/kg). During the exposure to a conditioned stressor of inescapable footshock, the higher, but not the lower dose of metyrapone attenuated fear-induced immobility. In contrast, the lower, but not the higher dose attenuated the anxiety state in an elevated plus-maze in a novel environment immediately after exposure to the conditioned stressor. It is suggested that emotion, learning, and memory are differentially affected by the different doses of metyrapone due to interference with different types of adrenal steroid receptors and consequent induction of various corticosterone receptor states.

ANXIOLYTIC-LIKE EFFECTS OF SELECTIVE MINERALOCORTICOID AND GLUCOCORTICOID ANTAGONISTS ON FEAR-ENHANCED BEHAVIOR IN THE ELEVATED PLUS-MAZE

The effects of intracerebroventricular (ICV) administration of the mineralocorticoid receptor (MR) antagonist, RU28318, and the glucocorticoid receptor (GR) antagonist, RU38486, were studied on behavior of rats exposed to a compartment previously associated with a stressor, and placed subsequently in an elevated plus-maze test. Fear-motivated immobility behavior was attenuated by the MR antagonist in a dose of 50 or 100 ng ICV, whereas the GR antagonist alone or simultaneous administration of both antagonists had no significant effect. In the elevated plus-maze, immediately after the exposure to the conditioned stressor, both the GR antagonist (50 ng) and MR antagonist (50 ng) increased the percentage of time the rats spent on open arms, and increased the amount of entries into these open arms. These data are interpretated in terms of the involvement of the GR and MR in fear and anxiety.

Enhanced 5-HT1A receptor expression in forebrain regions of aggressive house mice.

The brain 5-HT1A receptor system in male wild house mice selected for high and low offensive aggression was investigated by autoradiographic analysis of in situ hybridization and radioligand binding. In high-aggressive mice, characterized by a short attack latency, the rise in plasma corticosterone concentration during the early dark phase was reduced. At that time the level of 5-HT1A mRNA in the dorsal hippocampus (dentate gyrus and CA1) was twice the amount measured in low-aggressive mice that had long attack latency and high plasma corticosterone level. Increased postsynaptic 5-HT1A receptor radioligand binding was found in dentate gyrus, CA1, lateral septum, and frontal cortex. No difference in ligand binding was found for the 5-HT1A autoreceptor on cell bodies in the dorsal raphe nucleus. In conclusion, genetic selection for high offensive aggression co-selects for reduced (circadian peak) level in plasma corticosterone and increased postsynaptic 5-HT1A receptor number in limbic and cortical regions.

Exposure to chronic psychosocial stress and corticosterone in the rat: Effects on spatial discrimination learning and hippocampal protein kinase C gamma immunoreactivity

Previous reports have demonstrated a striking increase of the immunoreactivity of the γ‐isoform of protein kinase C (PKCγ‐ir) in Ammons horn and dentate gyrus (DG) of rodent hippocampus after training in a spatial orientation task. In the present study, we investigated how 8 days of psychosocial stress affects spatial discrimination learning in a hole board and influences PKCγ‐ir in the hippocampal formation.

Facilitation of memory consolidation by vasopressin: Mediation by terminals of the dorsal noradrenergic bundle?

Administration of arginine-vasopressin (AVP, 5 micrograms, s.c.) immediately after the learning trial results in a long-term facilitation of a one-trial learning passive avoidance response. This effect of AVP is absent in animals with prior destruction of the ascending dorsal noradrenergic bundle by bilateral microinjection of 6-hydroxydopamine (6-OHDA). Postlearning local microinjection of a minute amount of AVP via chronically implanted cannulae into the locus coeruleus did not influence passive avoidance behavior. Upon injection into the midbrain dorsal raphe nucleus, however AVP facilitated passive avoidance behavior. This effect, however, was absent in rats receiving previous microinjection of 5,6-dihydroxytryptamine (5,6-DHT) or of 6-OHDA into the dorsal raphe nucleus. Bilateral 6-OHDA-induced lesions of the nucleus accumbens or 5,6-DHT-induced destruction of the dorsal raphe nucleus did not prevent the effect of AVP administered subcutaneously. The data suggest that vasopressin facilitates memory consolidation processes by modulating noradrenergic neurotransmission in terminals of the dorsal noradrenergic bundle. The serotoninergic neuronal network originating from the dorsal raphe nucleus has a secondary--norepinephrine-mediated--influence upon these processes.