Lesions of parvocellular subdivisions of the hypothalamic paraventricular nucleus alter open field behavior and acquisition of sensory and spatial discrimination

Prolonged functional cerebral asymmetry as a consequence of dysfunctional parvocellular paraventricular hypothalamic nucleus signaling: An integrative model for the pathophysiology of bipolar disorder

Approximately 45 million people worldwide are diagnosed with bipolar disorder (BD). While there are many known risk factors and models of the pathologic processes influencing BD, the exact neurologic underpinnings of BD are unknown. We attempt to integrate the existing literature and create a unifying hypothesis regarding the pathophysiology of BD with the hope that a concrete model may potentially facilitate more specific diagnosis, prevention, and treatment of BD in the future. We hypothesize that dysfunctional signaling from the parvocellular neurons of the paraventricular hypothalamic nucleus (PVN) results in the clinical presentation of BD. Functional damage to this nucleus and its signaling pathways may be mediated by myriad factors (e.g. immune dysregulation and auto-immune processes, polygenetic variation, dysfunctional interhemispheric connections, and impaired or overactivated hypothalamic axes) which could help explain the wide variety of clinical presentations along the BD spectrum. The neurons of the PVN regulate ultradian rhythms, which are observed in cyclic variations in healthy individuals, and mediate changes in functional hemispheric lateralization. Theoretically, dysfunctional PVN signaling results in prolonged functional hemispheric dominance. In this model, prolonged right hemispheric dominance leads to depressive symptoms, whereas left hemispheric dominance correlated to the clinical picture of mania. Subsequently, physiologic processes that increase signaling through the PVN (hypothalamic-pituitaryadrenal axis, hypothalamic- pituitary-gonadal axis, and hypothalamic-pituitary-thyroid axis activity, suprachiasmatic nucleus pathways) as well as, neuro-endocrine induced excito-toxicity, auto-immune and inflammatory flairs may induce mood episodes in susceptible individuals. Potentially, ultradian rhythms slowing with age, in combination with changes in hypothalamic axes and maturation of neural circuitry, accounts for BD clinically presenting more frequently in young adulthood than later in life.

Garth J. Thomas, Physiological Psychologist: An Appraisal of His Contributions to Memory Research

This note is a tribute to Garth J. Thomas (1916-2008), late Professor of Brain Research at the University of Rochester, New York. Thomas was an influential psychologist, albeit for his research in learning and memory, as much as for his work as editor of the Journal of Comparative and Physiological Psychology. In his studies, he combined experimental lesions with behavioral analyses. He introduced the terms "dispositional" and "representational" to describe the 2 different types of memory function, and emphasized that memory must be studied not only through behavioristic psychology, but also in a molecular and physiological context. Through his experimentation in rodents, Thomas concluded that distinct neural mechanisms underpin dispositional and representational memory. Prompted by Thomas' remarks on the future evolution of research techniques, we touch upon some ideas on the engram and the glial theory in a modern perspective.

Disruption of Glucagon-Like Peptide 1 Signaling in Sim1 Neurons Reduces Physiological and Behavioral Reactivity to Acute and Chronic Stress

Organismal stress initiates a tightly orchestrated set of responses involving complex physiological and neurocognitive systems. Here, we present evidence for glucagon-like peptide 1 (GLP-1)-mediated paraventricular hypothalamic circuit coordinating the global stress response. The GLP-1 receptor (Glp1r) in mice was knocked down in neurons expressing single-minded 1, a transcription factor abundantly expressed in the paraventricular nucleus (PVN) of the hypothalamus. Mice with single-minded 1-mediated Glp1r knockdown had reduced hypothalamic-pituitary-adrenal axis responses to both acute and chronic stress and were protected against weight loss associated with chronic stress. In addition, regional Glp1r knockdown attenuated stress-induced cardiovascular responses accompanied by decreased sympathetic drive to the heart. Finally, Glp1r knockdown reduced anxiety-like behavior, implicating PVN GLP-1 signaling in behavioral stress reactivity. Collectively, these findings support a circuit whereby brainstem GLP-1 activates PVN signaling to mount an appropriate whole-organism response to stress. These results raise the possibility that dysfunction of this system may contribute to stress-related pathologies, and thereby provide a novel target for intervention.

SIGNIFICANCE STATEMENT

Dysfunctional stress responses are linked to a number of somatic and psychiatric diseases, emphasizing the importance of precise neuronal control of effector pathways. Pharmacological evidence suggests a role for glucagon-like peptide-1 (GLP-1) in modulating stress responses. Using a targeted knockdown of the GLP-1 receptor in the single-minded 1 neurons, we show dependence of paraventricular nucleus GLP-1 signaling in the coordination of neuroendocrine, autonomic, and behavioral responses to acute and chronic stress. To our knowledge, this is the first direct demonstration of an obligate brainstem-to-hypothalamus circuit orchestrating general stress excitation across multiple effector systems. These findings provide novel information regarding signaling pathways coordinating central control of whole-body stress reactivity.

Paraventricular Hypothalamic Mechanisms of Chronic Stress Adaptation

The hypothalamic paraventricular nucleus (PVN) is the primary driver of hypothalamo-pituitary-adrenocortical (HPA) responses. At least part of the role of the PVN is managing the demands of chronic stress exposure. With repeated exposure to stress, hypophysiotrophic corticotropin-releasing hormone (CRH) neurons of the PVN display a remarkable cellular, synaptic, and connectional plasticity that serves to maximize the ability of the HPA axis to maintain response vigor and flexibility. At the cellular level, chronic stress enhances the production of CRH and its co-secretagogue arginine vasopressin and rearranges neurotransmitter receptor expression so as to maximize cellular excitability. There is also evidence to suggest that efficacy of local glucocorticoid feedback is reduced following chronic stress. At the level of the synapse, chronic stress enhances cellular excitability and reduces inhibitory tone. Finally, chronic stress causes a structural enhancement of excitatory innervation, increasing the density of glutamate and noradrenergic/adrenergic terminals on CRH neuronal cell somata and dendrites. Together, these neuroplastic changes favor the ability of the HPA axis to retain responsiveness even under conditions of considerable adversity. Thus, chronic stress appears able to drive PVN neurons via a number of convergent mechanisms, processes that may play a major role in HPA axis dysfunction seen in variety of stress-linked disease states.

Effects of serotonin depletion on behavior and neuronal oxidative stress status in rat: relevance for anxiety and affective disorders

PURPOSE

We lesioned the hypothalamic paraventricular nucleus (PVN) of male Wistar rats using two different doses (8μg/3μl and 16μg/3μl) of 5,7-dihydroxytryptamine (5,7-DHT) and then animals were subjected to a battery of behavioral tests designed to assess anxiety and memory formation. Further, we were interested to know whether this lesion would result in neuronal oxidative stress and also if there is a correlation between the behavioral response to this lesion and brain oxidative stress.

MATERIAL/METHODS

Behavioral tests included elevated plus maze, used to assess exploration/anxiety status and radial armmaze, used for determining spatial short-term and reference memory errors. Regarding the oxidative stress, we measured the extent of some lipid peroxidation products like malondialdehyde and defense enzymes such as superoxide dismutase and glutathione peroxidase.

RESULTS

5,7-DHT lesioned rats spent more time in the open arms of the elevated maze compared to sham-operated rats, suggesting that the lesion significantly diminished anxiety-like behavior. Also, short-term memory was significantly impaired, as shown by the working memory errors in radial arm-maze task. Further analyses revealed that the 5,7-DHT lesion did not result in a significant change of reference memory errors. Regarding the oxidative stress, no significant modification of both superoxide dismutase and glutathione peroxidase specific activities from the temporal lobe were observed. However, the malondiadehyde level was significantly increased, suggesting pro-oxidant effects. Also, the linear regression between the working memory errors vs. malondiadehyde resulted in significant correlations.

CONCLUSION

5,7 DHT lesion of the PVN affects behavioral performance via interactions with systems governing novel and/or fear-evoking situations and also by increasing neuronal oxidative stress.

Blockade of NK3R signaling in the PVN decreases vasopressin and oxytocin release and c-Fos expression in the magnocellular neurons in response to hypotension

Tachykinin neurokinin 3 receptor (NK3R) signaling has a broad role in vasopressin (VP) and oxytocin (OT) release. Hydralazine (HDZ)-induced hypotension activates NK3R expressed by magnocellular neurons, increases plasma VP and OT levels, and induces c-Fos expression in VP and OT neurons. Intraventricular pretreatment with the specific NK3R antagonist, SB-222200, eliminates the HDZ-stimulated VP and OT release. NK3R are distributed in the central pathways conveying hypotension information to the magnocellular neurons, and the NK3R antagonist could act anywhere in the pathways. Alternatively, the antagonist could act at the NK3R expressed by the magnocellular neurons. To determine whether blockade of NK3R on magnocellular neurons impairs VP and OT release to HDZ, rats were pretreated with a unilateral PVN injection of 0.15 M NaCl or SB-222200 prior to an intravenous injection of 0.15 M NaCl or HDZ. Blood samples were taken, and brains were processed for VP/c-Fos and OT/c-Fos immunohistochemistry. Intravenous injection of 0.15 M NaCl did not alter plasma hormone levels, and little c-Fos immunoreactivity was present in the PVN. Conversely, intravenous injection of HDZ increased plasma VP and OT levels and c-Fos expression in VP and OT magnocellular neurons. Intra-PVN injection of SB-222200 prior to an intravenous injection of HDZ significantly decreased c-Fos expression in both VP and OT neurons by approximately 70% and attenuated plasma VP and OT levels by 33% and 35%, respectively. Therefore, NK3R signaling in magnocellular neurons has a critical role for the release of VP and OT in response to hypotension.

Effects of Morris water maze testing on the neuroendocrine stress response and intrahypothalamic release of vasopressin and oxytocin in the rat

Adult male Wistar rats were trained in the Morris water maze (MWM) on 3 consecutive days to find a visible platform. Concomitantly, microdialysis samples from the hypothalamic paraventricular (PVN) and supraoptic (SON) nuclei were collected in order to monitor local release of the neuropeptides vasopressin (AVP) and oxytocin (OXT), respectively, during controllable swim stress. Additionally, a separate set of animals was equipped with chronic jugular venous catheters to collect blood samples for analyzing plasma concentrations of corticotropin (ACTH) and corticosterone during training in the MWM. As measured by microdialysis, swimming in the MWM caused a significantly increased release of AVP within the PVN and of OXT within the SON on each of the 3 test sessions. In contrast to OXT in the SON, basal AVP concentrations in the PVN tended to rise from day to day. Plasma ACTH and corticosterone were found to be similarly elevated in response to MWM exposure on each of the test sessions. Taken together, these data demonstrate that testing in the MWM is not only associated with a significant activation of the hypothalamo-pituitary-adrenal axis but also with an intrahypothalamic release of AVP and OXT. If compared with findings using repeated forced swimming as an uncontrollable stressor (Wotjak, C.T., Ganster, J., Kohl, G., Holsboer, F., Landgraf, R., Engelmann, M., 1998. Dissociated central and peripheral release of vasopressin, but not oxytocin, in response to repeated swim stress: new insights into the secretory capacities of peptidergic neurons. Neuroscience 85, 1209-1222), the present results suggest that (1) similarities in the release profiles of AVP in the PVN and plasma hormone levels are fairly independent from the controllability of the stressor and seem, thus, to primarily relate to the physical demands of the task, whereas (2) the different intra-SON OXT release profiles might be linked to the controllability of the stressor.

Amygdala or ventral hippocampal lesions at two early stages of life differentially affect open field behaviour later in life; an animal model of neurodevelopmental psychopathological disorders

Psychiatric disorders like schizophrenia or autism are thought to result from disruption of the normal pattern of brain development. Abnormalities in the amygdaloid complex and hippocampus have been reported in these disorders. In the present study rats were lesioned in the amygdala or ventral hippocampus on day 7 of life (immature brain) or day 21 of life (almost mature brain) and open field behaviour was determined later in life before and after puberty. Lesioning on day 7 resulted in behavioural changes, interpreted as locomotor stereotypy and decreased anxiety in case of amygdala or hippocampus, respectively. These effects were more profoundly present after puberty. Lesioning on day 21 did not result in these behavioural changes, which subscribes to the importance of the stage of brain maturation on functional development. The results suggest that the behavioural changes in rats lesioned on day 7 may due to a malfunctioning of structures connected to the amygdala or ventral hippocampus. Brain lesions made on day 7 of life may serve as a potential model of psychopathological neurodevelopmental disorders.

Norepinephrine and serotonin receptors in the paraventricular nucleus interactively modulate ethanol consumption

The homeostatic function of the hypothalamus has long been recognized. In particular, the role of the paraventricular nucleus (PVN) in regulating ingestive behavior has been of interest. Infusions of serotonin and norepinephrine into the PVN are correlated with nutrient selective decreases and increases in consumatory behavior, respectively. Given the wide range of homeostatic functions of the hypothalamus, it is plausible that similar hypothalamic mechanisms may also be involved in the regulation of ethanol intake. This study examined the effects of PVN infusions of serotonin (5-HT) and norepinephrine (NE) on ethanol intake in a 1-hr limited-access two-bottle paradigm. When intake of 6% (v/v) ethanol versus water stabilized, male Wistar rats were implanted with stainless steel guide cannulae aimed at the PVN. After recovery, NE (20, 50, and 100 nmol), 5-HT (5 and 25 nmol), and their combination (NE 50 nmol + 5-HT 5 nmol) were microinjected into the PVN in a volume of 0.5 microliter/side over 1 min. Baseline ethanol intake was approximately 1.0 g/kg and ethanol preference (milliliters ethanol per total milliliters) was approximately 60%. Both 20 and 50 nmol of NE significantly increased absolute ethanol intake by 50% and relative ethanol intake by approximately 30%. Corresponding decreases were observed in water intake. Neither dose of 5-HT when administered alone altered ethanol or water consumption, but the 5-nmol dose of 5-HT attenuated the increase observed after NE (50 nmol) administration. These data demonstrate that NE and 5-HT receptors in the PVN interact in the modulation of ethanol ingestion. This finding suggests that homeostatic regulatory functions of the hypothalamus are involved in ethanol intake, and a perturbation of this system may influence excessive drinking.

Genetic analysis of the relationships between behavioral and neuroendocrine traits in Roman High and Low Avoidance rat lines

In order to determine whether the coselection observed between the selection trait (active avoidance behavior) of the Roman High Avoidance (RHA) and Roman Low Avoidance (RLA) rat lines and their neuroendocrine characteristics were genetically determined, we analyzed, in nonsegregating (RHA, RLA, and F1) and segregating (F2 and the two backcrosses) crosses, the inheritance pattern and the phenotypic correlations among behavioral (shuttle-box behavior), physiological (body, adrenal, and thymus weights), and neuroendocrine (corticosterone and prolactin reactivity, catecholamine enzyme activities) variables. Physiological characteristics and enzyme activities have a crucial role in sex dissociation. Avoidance behavior and prolactin reactivity to novel environment remained associated in segregating crosses despite gene rearrangement. They represented the most important variables to differentiate the Roman lines, perhaps sharing a common regulatory mechanism under genetic control.

Hypothalamic GABAA receptor blockade modulates cerebral cortical systems sensitive to acute stressors

Pharmacologic blockade of GABA binding sites in the hypothalamus elicits a pattern of physiological and behavioral arousal. The latter outcome implicates a perturbation in the neural functioning of higher brain centers. The effect that hypothalamic GABAA receptor modulation has on the function of cerebral cortical neural substrates linked with responses to stressors was assessed using microinfusion of bicuculline methiodide (BMI) into the medial hypothalamus of freely moving, handling habituated rats. BMI led to rapid increases in frontal cortical dopamine (DA) utilization (calculated from the sum of the levels of the DA metabolites, homovanilic and dihydroxyphenylacetic acids, divided by DA levels) resembling that identified following restraint-induced stress. Also, cortical GABAA receptor function [using chloride (Cl-) enhancement of 3H-flunitrazepam (Flu) binding as an index] was disrupted; i.e. there was a loss of typical Cl- enhancement of 3H-Flu binding in animals after BMI infusions. However, placing animals in restraint after BMI infusion reversed the effects of BMI, with both DA utilization and Cl- facilitated 3H-Flu binding similar to control basal values. Muscimol infusions in separately prepared animals did not alter either frontal cortical DA utilization or GABAA receptor function. The present results implicate GABA in the hypothalamus as "gating" activity of cortical systems involved in sensation of and/or responses to stressors. These findings may have important implications for effects of autonomic arousal on neural substrates involved in mediating stress responses.

Maturation of the behavioral and neuroendocrine differences between the Roman rat lines

The behavioral and/or neuroendocrine reactivity to psychological (open-field exposure) and physiological (CRF challenge) stimulations, as well as adrenal tyrosine hydroxylase (TH) and phenylethanolamine N-methyl transferase (PNMT) activities were measured, at different ages, in the Roman high avoidance (RHA) and Roman low avoidance (RLA) rat lines that have been genetically selected on the basis of their divergent active avoidance behavior. The highest locomotor activity in the open field, associated to blunted prolactin and renin reactivity to an emotional stress and lower specific TH and PNMT activities, characterized the RHA rats of all ages. HPA axis reactivity to psychological and/or physiological stimulations was identical in young animals (14 weeks old) of the two lines. Nevertheless, it displayed with age maturation processes, since the amplitude of postopen-field secretion peak for ACTH was larger in RLA rats from 20 weeks on, the response to CRF being not increased until 42 weeks. These maturation processes could result from genetically influenced changes related to environmental stimulations. Therefore, the Roman lines may be an excellent model to study the interactions between the genetic and developmental factors controlling the coupling between both behavioral and neuroendocrine functions.

Involvement of hypothalamic corticotropin-releasing factor neurons in behavioral responses to novelty in rats

The purpose of this experiment was to investigate whether endogenous corticotropin-releasing factor (CRF) within the paraventricular nucleus of the hypothalamus (PVN) is involved in the alteration of locomotor activity related to a novel, presumably stressful, environment in rats. Impairment of the function of CRF-containing neurons was effected by immunotargeting ricin A chain toxin to these cells with a monoclonal antibody to CRF (CRF-MAb/toxins). CRF-MAb/toxins administered into the PVN 2 weeks prior to testing produced an increase in locomotor activity during exposure to novel environment photocell cages. This behavioral activation was maintained throughout the 120 min experimental session, but was not present when the rats where introduced to the same photocell cages after extensive habituation. These results suggest that the effect induced by CRF-MAb/toxin treatment was related to the exploration of the novel environment, and was not due to a generalized locomotor hyperactivity. This effect was accompanied by a 53% and 61% CRF decrease in the hypothalamus and the median eminence, respectively. Injection of CRF-MAb/toxins into the ventromedial nucleus of the hypothalamus did not modify the locomotor activity in either unfamiliar or familiar conditions. These data suggest that CRF neurons within the PVN may participate not only in the activation of the pituitary adrenal axis associated with stressors but also as physiological mediators of the behavioral responses to stress.

Alterations in behavioral responses to stressors following excitotoxin lesions of dorsomedial hypothalamic regions

The dorsomedial hypothalamus is important for regulation of cardiovascular responses associated with emotional arousal. This region has also been identified as a component of neural circuitry involved in fear/anxiety, yet clear evidence as to the effects of lesioning on stress-related behaviors is missing. In this study, we lesioned the dorsomedial hypothalamic region with the neurotoxin, ibotenic acid (IBO; 2.0 micrograms in 0.2 microliter), and studied the impact on spontaneous and unlearned behavioral responses to stressors. In the open field test, we observed non-generalized increases in motility parameters in the IBO rats with the differences occurring in the latter two-thirds of the test. In the elevated plus-maze, the IBO rats displayed a classic anxiolytic response with a greater proportion of entries into (and greater time spent in) the open arms of the maze. In the environment-specific social interaction (SI) test, the IBO rats showed a normal familiar/unfamiliar environment discrimination with respect to Total SI; however, the composition of the behaviors ('curiosity' vs. physical contact) by the IBO rats was markedly altered, with there being a 2-fold increase in non-violent physical interactions. Additionally, the differences in these traditional indices of anxiety were associated with lesioned animals exhibiting greater acoustic startle responsiveness than controls as a function of prepulse intensity. Overall, the results following IBO lesions indicate an altered responsiveness to sudden stressors, particularly as relates to novelty or exploration-oriented behaviors. The hypothalamic lesion may, therefore, have resulted in a disinhibition of normally suppressed responding to innate fear or challenging stimuli. This study contributes to those that have begun to define neural interactions that are essential for integrated stress responses.