Dimitri De Bundel

The paraventricular thalamus controls a central amygdala fear circuit

Appropriate responses to an imminent threat brace us for adversities. The ability to sense and predict threatening or stressful events is essential for such adaptive behaviour. In the mammalian brain, one putative stress sensor is the paraventricular nucleus of the thalamus (PVT), an area that is readily activated by both physical and psychological stressors. However, the role of the PVT in the establishment of adaptive behavioural responses remains unclear. Here we show in mice that the PVT regulates fear processing in the lateral division of the central amygdala (CeL), a structure that orchestrates fear learning and expression. Selective inactivation of CeL-projecting PVT neurons prevented fear conditioning, an effect that can be accounted for by an impairment in fear-conditioning-induced synaptic potentiation onto somatostatin-expressing (SOM+) CeL neurons, which has previously been shown to store fear memory. Consistently, we found that PVT neurons preferentially innervate SOM+ neurons in the CeL, and stimulation of PVT afferents facilitated SOM+ neuron activity and promoted intra-CeL inhibition, two processes that are critical for fear learning and expression. Notably, PVT modulation of SOM+ CeL neurons was mediated by activation of the brain-derived neurotrophic factor (BDNF) receptor tropomysin-related kinase B (TrkB). As a result, selective deletion of either Bdnf in the PVT or Trkb in SOM+ CeL neurons impaired fear conditioning, while infusion of BDNF into the CeL enhanced fear learning and elicited unconditioned fear responses. Our results demonstrate that the PVT–CeL pathway constitutes a novel circuit essential for both the establishment of fear memory and the expression of fear responses, and uncover mechanisms linking stress detection in PVT with the emergence of adaptive behaviour.

Loss of system x(c)- does not induce oxidative stress but decreases extracellular glutamate in hippocampus and influences spatial working memory and limbic seizure susceptibility.

System xc− exchanges intracellular glutamate for extracellular cystine, giving it a potential role in intracellular glutathione synthesis and nonvesicular glutamate release. We report that mice lacking the specific xCT subunit of system xc− (xCT−/−) do not have a lower hippocampal glutathione content, increased oxidative stress or brain atrophy, nor exacerbated spatial reference memory deficits with aging. Together these results indicate that loss of system xc− does not induce oxidative stress in vivo. Young xCT−/− mice did however display a spatial working memory deficit. Interestingly, we observed significantly lower extracellular hippocampal glutamate concentrations in xCT−/− mice compared to wild-type littermates. Moreover, intrahippocampal perfusion with system xc− inhibitors lowered extracellular glutamate, whereas the system xc− activator N-acetylcysteine elevated extracellular glutamate in the rat hippocampus. This indicates that system xc− may be an interesting target for pathologies associated with excessive extracellular glutamate release in the hippocampus. Correspondingly, xCT deletion in mice elevated the threshold for limbic seizures and abolished the proconvulsive effects of N-acetylcysteine. These novel findings sustain that system xc− is an important source of extracellular glutamate in the hippocampus. System xc− is required for optimal spatial working memory, but its inactivation is clearly beneficial to decrease susceptibility for limbic epileptic seizures.

Identification and characterization of a new cognitive enhancer based on inhibition of insulin-regulated aminopeptidase

Approximately one‐quarter of people over the age of 65 are estimated to suffer some form of cognitive impairment, underscoring the need for effec tive cognitive‐enhancing agents. Insulin‐regulated ami nopeptidase (IRAP) is potentially an innovative tar get for the development of cognitive enhancers, as its peptide inhibitors exhibit memory‐enhancing effects in both normal and memory‐impaired rodents. Using a homology model of the catalytic domain of IRAP and virtual screening, we have identified a class of nonpeptide, small‐molecule inhibitors of IRAP. Structure‐based computational development of an initial “hit” resulted in the identification of two divergent families of compounds. Subsequent medicinal chemistry performed on the highest affinity compound produced inhibitors with nanomolar affinities (Ki 20‐700 nM) for IRAP. In vivo efficacy of one of these inhibitors was demonstrated in rats with an acute dose (1 nmol in 1 μl) administered into the lateral ventricles, improving performance in both spatial working and recognition memory paradigms. We have identified a family of specific IRAP inhibi tors that is biologically active which will be useful both in understanding the physiological role of IRAP and potentially in the development of clinically useful cogni tive enhancers. Notably, this study also provides unequiv ocal proof of principal that inhibition of IRAP results in memory enhancement.— Albiston, A. L., Morton, C. J., Ng, H. L., Pham, V., Yeatman, H. R., Ye, S., Ruani, N., Fernando, R. N., De Bundel, D., Ascher, D. B., Men delsohn, F. A. O., Parker, M. W., Chai, S. Y. Identification and characterization of a new cognitive enhancer based on inhibition of insulin‐regulated aminopeptidase. FASEB J. 22, 4209–4217 (2008)

Involvement of insulin-regulated aminopeptidase in the effects of the renin-angiotensin fragment angiotensin IV: a review.

For decades, angiotensin (Ang) II was considered as the end product and the only bioactive peptide of the renin–angiotensin system (RAS). However, later studies revealed biological activity for other Ang fragments. Amongst those, Ang IV has drawn a lot of attention since it exerts a wide range of central and peripheral effects including the ability to enhance learning and memory recall, anticonvulsant and anti-epileptogenic properties, protection against cerebral ischemia, activity at the vascular level and an involvement in atherogenesis. Some of these effects are AT1 receptor dependent but others most likely result from the binding of Ang IV to insulin-regulated aminopeptidase (IRAP) although the exact mechanism(s) of action that mediate the Ang IV-induced effects following this binding are until now not fully known. Nevertheless, three hypotheses have been put forward: since Ang IV is an inhibitor of the catalytic activity of IRAP, its in vivo effects might result from a build-up of IRAP’s neuropeptide substrates. Second, IRAP is co-localized with the glucose transporter GLUT4 in several tissue types and therefore, Ang IV might interact with the uptake of glucose. A final and more intriguing hypothesis ascribes a receptor function to IRAP and hence an agonist role to Ang IV. Taken together, it is clear that further work is required to clarify the mechanism of action of Ang IV. On the other hand, a wide range of studies have made it clear that IRAP might become an important target for drug development against different pathologies such as Alzheimer’s disease, epilepsy and ischemia.

Dopaminergic neurons of system xc−-deficient mice are highly protected against 6-hydroxydopamine-induced toxicity

Malfunctioning of system xc–, responsible for exchanging intracellular glutamate for extracellular cystine, can cause oxidative stress and excitotoxicity, both important phenomena in the pathogenesis of Parkinsons disease (PD). We used mice lacking xCT (xCT_/_ mice), the specific subunit of system xc˜, to investigate the involvement of this antiporter in PD. Although cystine that is imported via system xc˜ is reduced to cysteine, the rate‐limiting substrate in the synthesis of glutathione, deletion of xCT did not result in decreased glutathione levels in striatum. Accordingly, no signs of increased oxidative stress could be observed in striatum or substantia nigra of xCT_/_ mice. In sharp contrast to expectations, xCT_/_ mice were less susceptible to 6‐hydroxydopamine (6‐OHDA)‐induced neurodegeneration in the substantia nigra pars compacta compared to their age‐matched wild‐type littermates. This reduced sensitivity to a PD‐inducing toxin might be related to the decrease of 70% in striatal extracellular glutamate levels that was observed in mice lacking xCT. The current data point toward system xc˜ as a possible target for the development of new pharmacotherapies for the treatment of PD and emphasize the need to continue the search for specific ligands for system xc˜.—Massie, A., Schallier, A., Kim, S. W., Fernando, R., Kobayashi, S., Beck, H., De Bundel, D., Vermoesen, K., Bannai, S., Smolders, I., Conrad, M., Plesnila, N., Sato, H., Michotte, Y. Dopaminergic neurons of system xc “‐deficient mice are highly protected against 6‐hydroxydopamine‐induced toxicity. FASEB J. 25, 1359–1369 (2011). www.fasebj.org

Direct enhancement of hippocampal dopamine or serotonin levels as a pharmacodynamic measure of combined antidepressant–anticonvulsant action

The neurobiological relationships between epilepsy and depression are receiving increased experimental attention. A key role for limbic monoamines in depression has been established and we recently showed the importance of hippocampal monoamines in limbic seizure control. We here studied whether anticonvulsant compounds are antidepressant and can elevate hippocampal dopamine (DA) or serotonin (5-HT) levels determined by in vivo microdialysis in rats. We used assessment of seizure severity in the focal pilocarpine model, antidepressant-like activity within the rat forced swim and the mouse tail suspension tests, and locomotor activity in an open field as behavioural tests. We studied the tricyclic antidepressant imipramine, the selective 5-HT reuptake inhibitor citalopram and the selective DA reuptake blocker GBR-12909. These compounds with combined antidepressant-anticonvulsant properties all directly enhanced extracellular hippocampal DA or 5-HT levels. Since glutamate-mediated hyperexcitability in temporal lobe regions seems to be involved in disturbed emotional behaviour, we next investigated possible antidepressant effects and hippocampal DA or 5-HT modulations exerted by selective ionotropic and metabotropic glutamate receptor ligands with anticonvulsant properties. Combined anticonvulsant-antidepressant activities of the NMDA antagonist MK-801 and the mGluR group I antagonists (AIDA, MPEP) were also associated with locally elicited increases in hippocampal DA and/or 5-HT levels. This study highlights that the hippocampus is an important site of action of combined anticonvulsant-antidepressant and monoamine enhancing effects.

Involvement of the somatostatin‐2 receptor in the anti‐convulsant effect of angiotensin IV against pilocarpine‐induced limbic seizures in rats

The anti‐convulsant properties of angiotensin IV (Ang IV), an inhibitor of insulin‐regulated aminopeptidase (IRAP) and somatostatin‐14, a substrate of IRAP, were evaluated in the acute pilocarpine rat seizure model. Simultaneously, the neurochemical changes in the hippocampus were monitored using in vivo microdialysis. Intracerebroventricularly (i.c.v.) administered Ang IV or somatostatin‐14 caused a significant increase in the hippocampal extracellular dopamine and serotonin levels and protected rats against pilocarpine‐induced seizures. These effects of Ang IV were both blocked by concomitant i.c.v. administration of the somatostatin receptor‐2 antagonist cyanamid 154806. These results reveal a possible role for dopamine and serotonin in the anti‐convulsant effect of Ang IV and somatostatin‐14. Our study suggests that the ability of Ang IV to inhibit pilocarpine‐induced convulsions is dependent on somatostatin receptor‐2 activation, and is possibly mediated via the inhibition of IRAP resulting in an elevated concentration of somatostatin‐14 in the brain.

Ang II and Ang IV: unraveling the mechanism of action on synaptic plasticity, memory, and epilepsy.

The central angiotensin system plays a crucial role in cardiovascular regulation. More recently, angiotensin peptides have been implicated in stress, anxiety, depression, cognition, and epilepsy. Angiotensin II (Ang II) exerts its actions through AT1 and AT2 receptors, while most actions of its metabolite Ang IV were believed to be independent of AT1 or AT2 receptor activation. A specific binding site with high affinity for Ang IV was discovered and denominated “AT4 receptor”. The beneficiary effects of AT4 ligands in animal models for cognitive impairment and epileptic seizures initiated the search for their mechanism of action. This proved to be a challenging task, and after 20 years of research, the nature of the “AT4 receptor” remains controversial. Insulin‐regulated aminopeptidase (IRAP) was first identified as the high‐affinity binding site for AT4 ligands. Recently, the hepatocyte growth factor receptor c‐MET was also proposed as a receptor for AT4 ligands. The present review focuses on the effects of Ang II and Ang IV on synaptic transmission and plasticity, learning, memory, and epileptic seizure activity. Possible interactions of Ang IV with the classical AT1 and AT2 receptor subtypes are evaluated, and other potential mechanisms by which AT4 ligands may exert their effects are discussed. Identification of these mechanisms may provide a valuable target in the development in novel drugs for the treatment of cognitive disorders and epilepsy.

Angiotensin IV and LVV-haemorphin 7 enhance spatial working memory in rats: effects on hippocampal glucose levels and blood flow.

The IRAP ligands Angiotensin IV (Ang IV) and LVV-haemorphin 7 (LVV-H7) enhance performance in a range of memory paradigms in normal rats and ameliorate memory deficits in rat models for amnesia. The mechanism by which these peptides facilitate memory remains to be elucidated. In recent in vitro experiments, we demonstrated that Ang IV and LVV-H7 potentiate activity-evoked glucose uptake into hippocampal neurons. This raises the possibility that IRAP ligands may facilitate memory in hippocampus-dependent tasks through enhancement of hippocampal glucose uptake. Acute intracerebroventricular (i.c.v.) administration of 1nmol Ang IV or 0.1nmol LVV-H7 in 3 months-old Sprague-Dawley rats enhanced spatial working memory in the plus maze spontaneous alternation task. Extracellular hippocampal glucose levels were monitored before, during and after behavioral testing using in vivo microdialysis. Extracellular hippocampal glucose levels decreased significantly to about 70% of baseline when the animals explored the plus maze, but remained constant when the animals were placed into a novel control chamber. Ang IV and LVV-H7 did not significantly alter hippocampal glucose levels compared to control animals in the plus maze or control chamber. Both peptides had no effect on hippocampal blood flow as determined by laser Doppler flowmetry, excluding that either peptide increased the hippocampal supply of glucose. We demonstrated for the first time that Ang IV and LVV-H7 enhance spatial working memory in the plus maze spontaneous alternation task but no in vivo evidence was found for enhanced hippocampal glucose uptake or blood flow.

Brain and peripheral angiotensin II type 1 receptors mediate renal vasoconstrictor and blood pressure responses to angiotensin IV in the rat

Objectives Angiotensin (Ang) IV was reported to increase renal cortical blood flow (CBF) via putative angiotensin IV receptor (AT4) stimulation but reduce total renal blood flow (RBF) via angiotensin II type 1 (AT1) receptors. We investigated the effect of Ang IV on simultaneously measured mean arterial pressure (MAP), RBF, and CBF. The possible involvement of AT1 or AT4 receptors, the possible natriuretic effect, and responses to central administration were also explored. Methods and results Intravenous injections of Ang IV dose dependently increased MAP and decreased CBF and RBF; these effects were abolished by AT1 receptor blockade. These reductions in CBF and RBF highly correlated as did renal vascular responses to Ang II and fenoldopam. Ang IV did not induce renal vasodilation even following AT1 receptor blockade. Intrarenal Ang IV infusion reduced CBF and RBF but had no natriuretic effect. Central Ang IV administration induced an AT1-mediated immediate increase in MAP and renal vascular resistance and a secondary increase in RBF. AT4 selective ligands, LVV-hemorphin-7 and AT4-16 (intravenous, intrarenal or intracerebroventricular), had no effects on MAP, RBF or urinary sodium excretion. Additional in-vitro experiments indicated that the majority of the Ang IV-sensitive aminopeptidase activity in kidney membranes is attributed to aminopeptidase-N. Conclusion Insulin-regulated aminopeptidase (IRAP)/AT4 receptors are involved in neither the regulation of RBF or CBF nor in the handling of renal sodium. Ang IV increases MAP and induces renal vasoconstriction via stimulation of brain and peripheral AT1 receptors and may be involved in the regulation of renal blood flow and blood pressure.