Stress-sensitive organs and blood corticosterone after immobilization of active and passive rats immunized with glutamate-bovine serum albumin conjugate.

We studied stress-induced organ and hormonal responses in behaviorally active and passive rats against the background of immunization with glutamate-BSA conjugate. The relative weight of the adrenal glands after immobilization was lower in rats immunized with the conjugate in comparison with non-immunized animals. The weight of the adrenal glands in behaviorally active rats decreased in parallel with the decrease in blood corticosterone. In behaviorally active and passive rats immunized with the conjugate, ulcer formation in the stomach was slightly intensified after immobilization. It was hypothesized that immunization with glutamate-BSA conjugate suppresses activity of the hypothalamic-pituitary-adrenal feedback mechanism underlying the production of glucocorticoid hormones, which is manifested in slightly increased ulceration due to attenuation of the gastroprotective action of corticosterone under stress.

Enriched environment impacts trimethylthiazoline-induced anxiety-related behavior and immediate early gene expression: critical role of Crhr1.

It has been shown previously (Sotnikov et al., ) that mice selectively inbred for high anxiety-related behavior (HAB) vs. low anxiety-related behavior in the elevated plus maze differentially respond to trimethylthiazoline (TMT), a synthetic fox fecal odor. However, less is known about whether environmental factors can rescue these extreme phenotypes. Here, we found that an enriched environment (EE) provided during early adolescence induced anxiolytic effects in HAB (HAB-EE) mice, rescuing their strong avoidance behavior induced by TMT. In a series of experiments, the contribution of maternal, juvenile and adolescent behavior to the anxiolytic effects elicited by EE was investigated. At the molecular level, using c-fos expression mapping, we found that the activity of the medial and basolateral amygdala was significantly reduced in HAB-EE mice after TMT exposure. We further analysed the expression of Crhr1, as its amount in the amygdala has been reported to be important for the regulation of anxiety-related behavior after EE. Indeed, in situ hybridisation indicated significantly decreased Crhr1 expression in the basolateral and central amygdala of HAB-EE mice. To further test the involvement of Crhr1 in TMT-induced avoidance, we exposed conditional glutamatergic-specific Crhr1-knockout mice to the odor. The behavioral response of Crhr1-knockout mice mimicked that of HAB-EE mice, and c-fos expression in the amygdala after TMT exposure was significantly lower compared with controls, thereby further supporting a critical involvement of Crhr1 in environmentally-induced anxiolysis. Altogether, our results indicate that EE can rescue strong avoidance of TMT by HAB mice with Crhr1 expression in the amygdala being critically involved.

Bidirectional rescue of extreme genetic predispositions to anxiety: impact of CRH receptor 1 as epigenetic plasticity gene in the amygdala.

The continuum of physiological anxiety up to psychopathology is not merely dependent on genes, but is orchestrated by the interplay of genetic predisposition, gene x environment and epigenetic interactions. Accordingly, inborn anxiety is considered a polygenic, multifactorial trait, likely to be shaped by environmentally driven plasticity at the genomic level. We here took advantage of the extreme genetic predisposition of the selectively bred high (HAB) and low anxiety (LAB) mouse model exhibiting high vs low anxiety-related behavior and tested whether and how beneficial (enriched environment) vs detrimental (chronic mild stress) environmental manipulations are capable of rescuing phenotypes from both ends of the anxiety continuum. We provide evidence that (i) even inborn and seemingly rigid behavioral and neuroendocrine phenotypes can bidirectionally be rescued by appropriate environmental stimuli, (ii) corticotropin-releasing hormone receptor 1 (Crhr1), critically involved in trait anxiety, shows bidirectional alterations in its expression in the basolateral amygdala (BLA) upon environmental stimulation, (iii) these alterations are linked to an increased methylation status of its promoter and, finally, (iv) binding of the transcription factor Yin Yang 1 (YY1) to the Crhr1 promoter contributes to its gene expression in a methylation-sensitive manner. Thus, Crhr1 in the BLA is critically involved as plasticity gene in the bidirectional epigenetic rescue of extremes in trait anxiety.

[Immune links in the system organization of behaviour].

The work is devoted to the research of immune mechanisms in self-control of various functional systems of homeostatic and behavioral levels. Distinction of immune mechanisms in rats with different prognostic stress-resistance is established. Immunization of rats by conjugates of various neuromediators with bovine serum albumin selectively changes the animals stress-resistance. Participation cytokines in reactions of a brain's separate neurons and their interaction with a leading neuromediator - norepinephrine is established. Individual changes of pro- and anti-inflammatory cytokines in blood serum are shown in rats with different stress-resistance. There are revealed features of morphological distinctions of immunogenic structures small intestine fabrics in animals with various behavioral activity in the "Open field" test.

Genetic predisposition to anxiety-related behavior predicts predator odor response.

While rodents have a keen sense of smell and largely depend on olfactory cues for operating in their environment, most of the widely used tests to assess anxiety-related behavior largely ignore the olfactory system, being primarily based on fear of brightly lit, novel and open spaces. Here, we aimed at testing whether the genetic predisposition to anxiety predicts the predator odor response in mice. In the first experiment, using the 3-chamber avoidance test in CD-1 mice, trimethylthiazoline (TMT), a synthetic fox fecal odor, was shown to induce stronger behavioral and neuroendocrine effects than cat odor and butyric acid, respectively, and was therefore chosen as aversive odor for the following series of experiments. In this series, bidirectionally, selectively inbred CD-1 mice with either high (HAB), intermediate (NAB) or low (LAB) anxiety-related behavior responded differently to TMT, with HABs spending significantly less time than both NABs and LABs in the chamber harbouring the predator odor. Importantly, this result is not confounded by any deficit of the olfactory system, as LAB and NAB mice, while not or only moderately responding to TMT, responded to both the pleasant odor of female urine and the repugnant odor of butyric acid. Probably due to the strength of TMT, a similar increase in corticosterone levels upon predator odor exposure was observed in all three groups. Together, the results suggest that, dependent on the genetic predisposition to extremes in anxiety-related behavior, mice differentially interpret the odor of a potential predator, making this type of avoidance behavior highly predictable.

Changes in ß-endorphin level in the cingulate cortex in rats after peripheral loperamide and methylnaloxone administration at rest and during emotional stress.

ß-Endorphin content in the extracellular space of rat cingulate cortex was measured using intravital microdialysis followed by ELISA. Intragastric administration of µ-opioid ligands loperamide and methylnaloxone not crossing the blood-brain barrier produced different effects on ß-endorphin level: loperamide reduced and methylnaloxone significantly increased the release of ß-endorphin into the extracellular space of rat cingulate cortex. Emotional stress caused by immobilization resulted in slight increase in ß-endorphin level in the cingulate cortex. Peripheral administration of loperamide (but not methylnaloxone) significantly increased the release of the neuropeptide during stress. These findings support our hypothesis of reciprocal interaction between the central and peripheral compartments of the endogenous opioid system and provide explanations for the anti-stress effects of loperamide.

[Influence of exposure to immobilisation stress on blood concentration of TNF alpha and IL-4 in rats active and passive in the open field test].

The influence of exposure to immobilization stress on TNF alpha and IL-4 concentrations in blood was studied in behaviorally active vs. passive in the open field Wistar rats. One hour after exposure to stress, blood concentrations of TNF alpha and IL-4 were significantly lower in behaviorally passive as compared to active rats and passive controls not exposed to stress. Moreover, in passive rats exposed to stress, the pituitary weight increased as compared to passive controls. Behaviorally passive rats exposed to emotional stress were characterized by a decreased blood levels of TNF alpha and IL-4 as compared to behaviorally passive controls and behaviorally active animals exposed to stress.

Involvement of autoantibodies to neurotransmitters in mechanisms of stress reaction in rats.

Combined stress exposure of rats can lead to the formation of autoantibodies to neurotransmitters. Repeated stress is associated with the production of autoantibodies to serotonin, dopamine, norepinephrine, glutamate, and GABA. High emotional and behavioral reaction to stress is associated with intensive production of autoantibodies to serotonin, dopamine, norepinephrine, and glutamate.