Simone A. Krömer

Identification of Glyoxalase-I as a Protein Marker in a Mouse Model of Extremes in Trait Anxiety

For >15 generations, CD1 mice have been selectively and bidirectionally bred for either high-anxiety-related behavior (HAB-M) or low-anxiety-related behavior (LAB-M) on the elevated plus-maze. Independent of gender, HAB-M were more anxious than LAB-M animals in a variety of additional tests, including those reflecting risk assessment behaviors and ultrasound vocalization, with unselected CD1 “normal” control (NAB-M) and cross-mated (CM-M) mice displaying intermediate behavioral scores in most cases. Furthermore, in both the forced-swim and tail-suspension tests, LAB-M animals showed lower scores of immobility than did HAB-M and NAB-M animals, indicative of a reduced depression-like behavior. Using proteomic and microarray analyses, glyoxalase-I was identified as a protein marker, which is consistently expressed to a higher extent in LAB-M than in HAB-M mice in several brain areas. The same phenotype-dependent difference was found in red blood cells with NAB-M and CM-M animals showing intermediate expression profiles of glyoxalase-I. Additional studies will examine whether glyoxalase-I has an impact beyond that of a biomarker to predict the genetic predisposition to anxiety- and depression-like behavior.

Brain oxytocin inhibits the (re)activity of the hypothalamo–pituitary–adrenal axis in male rats: involvement of hypothalamic and limbic brain regions

In response to various stressors, oxytocin is released not only into blood, but also within hypothalamic and extrahypothalamic limbic brain regions. Here, we describe the involvement of intracerebrally released oxytocin in the regulation of the activity of the hypothalamo-pituitary-adrenal (HPA) axis by infusion of the oxytocin receptor antagonist (des Gly-NH(2) d(CH(2))(5) [Tyr(Me)(2), Thr(4)] OVT; pH 7.4; Dr. M. Manning, Toledo, OH, USA) either into the lateral cerebral ventricle (icv[0.75 microg/5 microl,]) or via retrodialysis (10 microg/ml, 3.3 microl/min, 15 min) into the hypothalamic paraventricular nuclei (PVN), the medio-lateral septum or the amygdala. Male Wistar rats fitted with a chronic jugular vein catheter and an icv guide cannula or a microdialysis probe targeting the respective brain region 4 days prior to the experiment were blood sampled under basal as well as stressful conditions. Rats were exposed to the elevated platform (emotional stressor) and/or to forced swimming (combined physical and emotional stressor). Blockade of the receptor-mediated action of endogenous oxytocin within the PVN resulted in an enhanced basal secretion of ACTH whereas, in response to forced swimming, ACTH secretion was rather reduced, indicating a tonic inhibitory effect of OXT on basal HPA axis activity, but a potentiating action under conditions of stress. Within the medio-lateral septum, antagonist treatment did not alter basal ACTH secretion, but significantly disinhibited ACTH secretion in response to the elevated platform, but not to forced swimming. Within the amygdala, no significant effects either on basal or stress-induced HPA axis activity could be found. The results indicate a differential involvement of brain oxytocin in the regulation of the HPA axis activity which depends both on the site of intracerebral oxytocin release and the stressor the animals are exposed to.

Release of oxytocin in the rat central amygdala modulates stress-coping behavior and the release of excitatory amino acids

Previous experiments have indicated that the release of oxytocin (OXT) occurs in various hypothalamic and extrahypothalamic brain areas. In the present study, we investigated in male rats whether swim stress triggers the release of OXT in the central amygdala (CeA), a key area in processing emotions and stress responses. Further, we examined the physiological significance of OXT released within the CeA for behavioral responses during forced swimming as well as effects on the local release of selected amino acids including glutamate, aspartate, arginine, taurine, and GABA, which are thought to modulate processing of emotions. Exposure to a 10-min forced swimming session caused a significant increase in OXT release (200%, p<0.01) within, but not outside, the CeA as monitored by microdialysis. Administration of the OXT receptor antagonist des-Gly-NH2d(CH2)5(Tyr(Me)2Thr4)OVT via inverse microdialysis into the amygdala before and during exposure to swimming reduced the floating time by 55% (p<0.05) and increased the swimming time by 29% (p<0.05) indicative of a more active stress-coping strategy. Simultaneously, local administration of the OXT receptor antagonist caused a significant increase in the stress-induced release of the excitatory amino acids glutamate and aspartate, whereas the basal release of these amino acids remained unchanged. Taken together, these findings demonstrate a significant activation of the oxytocinergic system in the CeA in response to swim stress. Furthermore, our data indicate that OXT receptor-mediated mechanisms within the amygdala are involved in the generation of passive stress-coping strategies, which might be mediated at least in part via its inhibitory influence on the local release of excitatory amino acids during stress.

Maternal defence as an emotional stressor in female rats: Correlation of neuroendocrine and behavioural parameters and involvement of brain oxytocin.

In order to study neuroendocrine and behavioural stress responses in female rats post partum we aimed to establish a relevant emotional stressor – the maternal defence test based on maternal aggression of a lactating resident towards a virgin or lactating intruder approaching the cage. Exposure to maternal defence significantly elevated corticotropin (ACTH) and corticosterone responses of the residents and of virgin or lactating intruders, with an attenuated response in lactating residents and lactating intruders. Exposure to maternal defence increased plasma oxytocin in virgin intruders only. The aggressive behaviour displayed by the residents was directly correlated with the amount of defensive behaviour of the intruder and independent of the intruders reproductive state. However, the amount of maternal and explorative behaviours displayed by the lactating residents was significantly higher when exposed to a lactating, compared to a virgin, intruder. ACTH responses in lactating residents exposed to virgin intruders were significantly correlated to the amount of offensive (direct correlation) and maternal (inverse correlation) behaviours they displayed. Plasma prolactin concentrations, elevated in lactating compared to virgin rats under basal conditions, were found to be reduced in the lactating residents and intruders in response to exposure to the maternal defence test, whereas it was unchanged in virgin intruders. To test for the involvement of brain oxytocin in neuroendocrine and behavioural responses of the lactating residents an oxytocin receptor antagonist (0.1 µg/5 µL) was infused icv 10 min prior to testing. This treatment increased basal, but not stress‐induced, ACTH, corticosterone and oxytocin secretion. Whereas parameters of aggressive behaviour were unchanged, the antagonist reduced signs of maternal behaviour during maternal defence. In summary, the maternal defence test has been characterized as a relevant emotional stressor for female rats which is useful for studying neuroendocrine and emotional responses in females, in particular in the context of reproductive adaptations.

Prenatal stress reduces postnatal neurogenesis in rats selectively bred for high, but not low, anxiety: possible key role of placental 11β‐hydroxysteroid dehydrogenase type 2

Prenatal stress (PS) produces persistent abnormalities in anxiety‐related behaviors, stress responsivity, susceptibility to psychopathology and hippocampal changes in adult offspring. The hippocampus shows a remarkable degree of structural plasticity, notably in response to stress and glucocorticoids. We hypothesized that PS would differentially affect hippocampal neurogenesis in rats selectively bred for genetic differences in anxiety‐related behaviors and stress responsivity. Pregnant dams of high anxiety‐related behavior (HAB) and low anxiety‐related behavior (LAB) strains were stressed between days 5 and 20 of pregnancy. The survival of newly generated hippocampal cells was found to be significantly lower in 43‐day‐old HAB than in LAB male offspring of unstressed pregnancies. PS further reduced newly generated cell numbers only in HAB rats, and this was paralleled by a reduction in doublecortin‐positive cell numbers, indicative of reduced neurogenesis. As maternal plasma corticosterone levels during PS were similar in both strains, we examined placental 11β‐hydroxysteroid dehydrogenase type 2 (11β‐HSD2), which catalyses rapid inactivation of maternal corticosterone to inert 11‐dehydrocorticosterone and thus serves as a physiological ‘barrier’ to maternal glucocorticoids. PS significantly increased placental 11β‐HSD2 activity in LAB, but not HAB, rats. We conclude that PS differentially affects the number of surviving newly generated cells and neurogenesis in HAB and LAB rats. The high sensitivity of hippocampal neurogenesis to PS in HAB rats is paralleled by a failure to increase placental 11β‐HSD2 activity after stress rather than by different maternal corticosterone responses. Hence, stress‐induced placental 11β‐HSD2 expression may be critical in protecting the fetal brain from maternal stress‐induced effects on adult neurogenesis.

Prenatal stress: opposite effects on anxiety and hypothalamic expression of vasopressin and corticotropin-releasing hormone in rats selectively bred for high and low anxiety.

We studied the mechanisms of genetic–early environmental interactions to modulate adult stress‐coping and tested the hypothesis that prenatal stress (PS) can differentially alter the consequences of a genetic predisposition to either hyper‐ or hypo‐anxiety. Exposure of male Wistar rats, bred for high (HAB) or low (LAB) anxiety‐related behaviour, to PS between pregnancy days 4 and 18 resulted in opposite effects on anxiety in adulthood, i.e. HAB rats became less and LAB rats became more anxious compared with their unstressed controls (plus‐maze and holeboard). The high anxiety of HAB controls was accompanied by elevated expression of vasopressin and corticotropin‐releasing hormone (CRH) mRNA within the hypothalamic paraventricular nucleus compared with LAB rats. PS reduced CRH mRNA expression in HAB rats but increased vasopressin mRNA expression in LAB rats, which may explain the opposite effects of PS on adult emotionality. Differential effects of PS were also found with respect to hypothalamo‐pituitary‐adrenal axis reactivity; the hypothalamo‐pituitary‐adrenal hyper‐response in virgin female HAB controls became attenuated after PS, without affecting plasma corticosterone concentrations in LAB rats. Differences in maternal plasma corticosterone measured between pregnancy days 6 and 14 of HAB and LAB dams or differential effects of PS on maternal behaviour can be excluded. In conclusion, exposure of rats with genetically determined high or low emotionality to PS mitigates the extremes in behavioural and neuroendocrine stress‐coping, thus allowing adequate and similar behavioural responses to potentially dangerous stimuli in adulthood. Differential effects of PS on the activity of the brain vasopressin and CRH systems might represent possible underlying molecular mechanisms.

Release of oxytocin in the hypothalamic paraventricular nucleus, but not central amygdala or lateral septum in lactating residents and virgin intruders during maternal defence

In lactating rats, the neuroendocrine responses of the oxytocinergic system and the hypothalamo-pituitary-adrenal axis to various kinds of stressors are attenuated. In this study, using intracerebral microdialysis in combination with a highly sensitive radioimmunoassay, we characterised oxytocin (OXT) release within the paraventricular nucleus (PVN), the central amygdala (CeA), and the medio-lateral septum (mS) before, during and after a psycho-social stressor (the maternal defence test) in both the virgin intruder and the lactating resident rat (day 3 of lactation). Within the PVN, local OXT release was found to increase significantly in virgin intruders during exposure to the resident (2.1-fold, P < 0.05), as well as in lactating residents when exposed to the virgin intruder, though to a lesser extent when compared with basal levels (1.7-fold, P < 0.05). In contrast, OXT release remained unchanged within the CeA and the mS of both virgin intruders and lactating residents. Release of OXT under basal conditions was clearly above the detection limit of the radioimmunoassay, and did not differ between lactating and virgin rats in any of the brain regions studied. Our study also demonstrates that recent surgery or ongoing intracerebral microdialysis does not affect the behavioural performance of the intruders or residents when comparing dialysed and non-dialysed rats. The results indicate that exposure to the maternal defence test is a relevant stressor for the brain OXT system which becomes activated in both intruder and resident rats, although to varying degrees depending upon their reproductive status and in a region-dependent manner. The behavioural and/or neuroendocrine functions of intra-PVN released OXT during this psycho-social challenge remain to be clarified.

Effects of psycho-social stress during pregnancy on neuroendocrine and behavioural parameters in lactation depend on the genetically determined stress vulnerability

The neuroendocrine consequences of repeated exposure of the pregnant mother to relevant stressors have been studied in the offspring, but not in the mothers. As these stress effects might depend on the genetically determined stress susceptibility of the dams, here, we investigated the effects of daily exposure to psycho-social stressors (maternal defeat by an aggressive lactating resident and restraint) between pregnancy days 4 and 18 in female rats selectively and bidirectionally bred for high (HAB) or low (LAB) anxiety-related behaviour. ACTH and corticosterone secretory responses to a mild stressor were found to be low in unstressed lactating HAB and LAB dams (day 8 of lactation) indicating an intact physiological attenuation of the HPA axis at this time. Pregnancy stress significantly increased the reactivity of the hypothalamo-pituitary-adrenal (HPA) axis in lactating HAB, but not LAB rats, reflecting impaired attenuation of the HPA axis selectively in pregnancy-stressed HAB dams. The high and low anxiety phenotypes were consistent in lactation and not significantly altered by pregnancy stress, despite an elevated level of arousal in pregnancy-stressed HAB dams. In general, HAB dams showed signs of a more protective maternal behaviour compared to LAB dams: (i) in the home cage, HAB dams spent more time in direct pup contact (day 1 of lactation), (ii) during two forms of the pup retrieval test, differing in the level of challenging the dam, HAB dams retrieved the pups faster, and (iii) during the maternal defence test, they were more aggressive towards a virgin intruder compared to LAB and NAB dams. Pregnancy stress did not alter any of these behavioural measures, except an increase in the speed of pup collection in a novel environment in HAB dams and increased maternal aggression in LAB dams. The results indicate a robust behavioural phenotype of HAB and LAB dams with respect to anxiety and maternal behaviour which was found to be almost unchanged by exposure to pregnancy stress. However, the finding of differential effects of pregnancy stress on the attenuation of the reactivity of the HPA axis in lactation makes HAB and LAB rats a potential animal model for studying genetically determined differences in stress vulnerability and stress-induced maladaptation of the HPA axis post-partum.

Differential effects of periodic maternal separation on adult stress coping in a rat model of extremes in trait anxiety

We studied interactions of genetic and environmental factors shaping adult emotionality and stress coping, and tested the hypothesis that repeated periodic maternal deprivation (PMD) exerts differential effects on adult behavioral and neuroendocrine stress responsiveness in dependence on the genetic predisposition to either hyper- or hypo-anxiety. Exposure of male Wistar rats bidirectionally bred for either high (HAB) or low (LAB) anxiety-related behavior to PMD between postnatal days 2 and 15 resulted in a behavioral approximation of the selected lines. This was reflected by test-dependent signs of reduced anxiety-related behavior in adult HAB rats and of enhanced levels of anxiety in LAB rats compared with their corresponding unstressed controls. In addition to behavioral parameters, differential effects of PMD were also seen with respect to the responsiveness of the hypothalamo-pituitary-adrenocortical axis to acute stressor exposure (novel environment) in adulthood. The corticotrophin (ACTH) and corticosterone hyper-responses seen in control rats of the HAB line compared with those of the LAB line became attenuated in PMD-HAB rats, whereas PMD did not significantly alter neuroendocrine responses in LAB rats. Thus, as a result of PMD, both ACTH and corticosterone responses became indistinguishable between HAB and LAB rats. Although HAB dams spent more time on the nest with the litter compared with LAB dams during the first 5 days postpartum, licking and grooming behavior did not differ between the lines prior to separation, and was found to be increased to the same extent in both HAB and LAB dams during the first hour immediately after reunion with the pups. In contrast to early life stress, exposure of adult HAB and LAB rats to a 10-day unpredictable stress schedule failed to alter their emotional measures. The mitigating effect of PMD on both behavioral and neuroendocrine parameters in rats representing extremes in trait anxiety might reflect an evolutionary benefit as the genetic variability among individuals of a species is sustained while allowing adequate responses to potentially dangerous stimuli in adulthood dependent on early life conditions.

Protein Biomarkers in a Mouse Model of Extremes in Trait Anxiety

Brain proteome analysis of mice selectively bred for either high or low anxiety-related behavior revealed quantitative and qualitative protein expression differences. The enzyme glyoxalase-I was consistently expressed to a higher extent in low anxiety as compared with high anxiety mice in several brain areas. The same phenotype-dependent difference was also found in red blood cells with normal and cross-mated animals showing intermediate expression profiles of glyoxalase-I. Another protein that showed a different mobility during two-dimensional gel electrophoresis was identified as enolase phosphatase. The presence of both protein markers in red or white blood cells, respectively, creates the opportunity to screen for their expression in clinical blood specimens from patients suffering from anxiety.