Role of the Ventral Hippocampus in Exploration and Ventral Hippocampal Parvalbumin Neurons in Behaviors relevant to Schizophrenia

Nguyen, Robin

26 November 2012

We conducted experiments to understand the role of Ventral Hippocampus (vHPC) projections to the Nucleus Accumbens (NAc) in exploratory locomotion, and to determine if the reduced vHPC parvalbumin neuron activity can result in behaviors associated with schizophrenia. Through the use of optogenetics, we activated vHPC neurons and vHPC terminals in the NAc. Both manipulations significantly increased locomotor activity in the open field. Selective inhibition of vHPC terminals in the NAc during a test for novel environment exploration significantly reduced preference for novel environments over familiar environments. DREADD-mediated inhibition of activation of vHPC parvalbumin neuron activity did not significantly alter amphetamine-induced locomotion. Overall, these experiments provide support for the role of the vHPC-NAc pathway in mediating exploratory behavior in novel environments, but it remains inconclusive whether dysregulated vHPC activity due to the loss of parvalbumin neurons leads to behaviors associated with schizophrenia.

ventral hippocampus

exploration

parvalbumin

optogenetics

DREADD

0384

0317

Role of the Ventral Hippocampus in Exploration and Ventral Hippocampal Parvalbumin Neurons in Behaviors relevant to Schizophrenia

Nguyen, Robin

26 November 2012

We conducted experiments to understand the role of Ventral Hippocampus (vHPC) projections to the Nucleus Accumbens (NAc) in exploratory locomotion, and to determine if the reduced vHPC parvalbumin neuron activity can result in behaviors associated with schizophrenia. Through the use of optogenetics, we activated vHPC neurons and vHPC terminals in the NAc. Both manipulations significantly increased locomotor activity in the open field. Selective inhibition of vHPC terminals in the NAc during a test for novel environment exploration significantly reduced preference for novel environments over familiar environments. DREADD-mediated inhibition of activation of vHPC parvalbumin neuron activity did not significantly alter amphetamine-induced locomotion. Overall, these experiments provide support for the role of the vHPC-NAc pathway in mediating exploratory behavior in novel environments, but it remains inconclusive whether dysregulated vHPC activity due to the loss of parvalbumin neurons leads to behaviors associated with schizophrenia.

ventral hippocampus

exploration

parvalbumin

optogenetics

DREADD

0384

0317

Separate basolateral amygdala projections to the hippocampal formation differentially modulate the consolidation of contextual and emotional learning

Huff, Mary Louise

01 December 2016

Previous research investigating the neural circuitry underlying memory consolidation has primarily focused on single “nodes” in the circuit rather than the neural connections between brain regions, despite the likely importance of these connections in mediating different aspects or forms of memory. This focus has, in part, been due to technical limitations; however the advent of optogenetics has altered our capabilities in this regard, enabling optical control over neural pathways with temporal and spatial precision. The current set of experiments took advantage of optogenetics to control activity in specific pathways connecting brain regions in rats immediately after different kinds of learning. Chapter 2 first established the use of optogenetics to manipulate activity in the basolateral amygdala (BLA), which has been shown to modulate memory consolidation for a variety of types of learning likely through its connections to various downstream regions. Using a one-trial inhibitory avoidance task, a simple and robust fear learning paradigm, we found that both post-training stimulation and inhibition of BLA activity could enhance or impair later retention of the task, respectively. Enhancement was specific to stimulation using trains of 40, but not 20, Hz light pulses. Chapters 3 and 4 examined the projections from the BLA to the ventral hippocampus (VH) and medial entorhinal cortex (mEC) as the BLA’s ability to influence the consolidation for many types of memory is believed to be mediated through discrete projections to distinct brain regions. Indeed, the BLA innervates both structures, and prior studies suggest that the mEC and VH have distinct roles in memory processing related to contextual and nociceptive (footshock) learning, such as those involved in contextual fear conditioning (CFC). Optogenetic stimulation or inhibition of the BLA-VH or BLA-mEC pathway after training on a modified CFC task, in which the nociceptive or emotional stimulus (the footshock) and the context are separated, enabled experimental manipulations to selectively affect the consolidation for learning about one component and not the other. Optogenetic stimulation/inhibition was given to each candidate pathway immediately after the relevant training to determine its role in influencing consolidation for that component of the CFC learning. Chapter 3 results showed that stimulation of the BLA-VH pathway following footshock, but not context, training enhanced retention, an effect that was specific to trains of 40 Hz stimulation. Post-footshock photoinhibition of the same pathway impaired retention for the task. Similar investigations of the BLA-mEC pathway in Chapter 4 produced complementary findings. Post-context, but not footshock, stimulation of the pathway enhanced retention. In this particular case, only trains of 8 Hz stimulation were effective at enhancing retention. These results are the first, to our knowledge, to find that BLA inputs to different structures selectively modulate consolidation for different aspects of learning, thus enhancing our understanding of the neural connections underlying the consolidation of contextual fear conditioning and providing a critical foundation for future research.

basolateral amygdala

contextual fear conditioning

medial entorhinal cortex

Memory Consolidation

Optogenetics

ventral hippocampus

Psychology

Transient Inactivation of the Neonatal Ventral Hippocampus Disrupts Mesolimbic Regulation of Prefrontal Glutamate Release

Bortz, David Michael

18 December 2012

No description available.

Neurosciences

Psychobiology

Psychology

Schizophrenia

Animal Model

Ventral Hippocampus

Prefrontal Cortex

Glutamate

Micro-Electrode Array

Συγκριτική μελέτη της έκφρασης των υπομονάδων του GABAA υποδοχέα και των πρώιμων γονιδίων c-fos και zif-268 σε Τομές από τον διαφραγματικό και τον κροταφικό ιππόκαμπο επίμυος πριν καθώς και κατά την διάρκεια της ανάπτυξης των "in vitro" οξέων κυμάτων / Comparative study of GABAA receptor subunits and early genes(c-fos,zif-268)mRNA expression in dorsal and ventral hippocampus before and during the development of the "in vitro sharp waves"

Σωτηρίου, Ευάγγελος

27 June 2007

Ο σκοπός της παρούσας διδακτορικής διατριβής ήταν η μελέτη της έκφρασης των υπομονάδων του GABAΑ υποδοχέα σε τομές από τον διαφραγματικό και τον κροταφικό ιππόκαμπο αμέσως μετά την θανάτωση του ζώου και κατά την διάρκεια της ανάπτυξης των "in vitro" οξέων κυμάτων που έχουν παρατηρηθεί μόνο σε τομές του κροταφικού ιππόκαμπου. Επιπλέον, μελετήθηκε η ποσοτική και τοπογραφική κατανομή των Α1 υποδοχέων αδενοσίνης με την χρήση του ραδιενεργού ιχνηθέτη [3H]-CHA (αγωνιστής των Α1 υποδοχέων) στον κροταφικό και τον διαφραγματικό ιππόκαμπο αμέσως μετά την θανάτωση του επίμυος. Η μελέτη της κατανομής των Α1 υποδοχέων αδενοσίνης έδειξε ότι η δέσμευση της [3H]-CHA ήταν μικρότερη στον κροταφικό σε σύγκριση με τον διαφραγματικό ιππόκαμπο με την μεγαλύτερη διαφορά να εντοπίζεται στην CA1 περιοχή. Το παραπάνω αποτέλεσμα έρχεται σε συμφωνία με την υπόθεση, ότι οι συνάψεις του κροταφικού ιππόκαμπου εμφανίζουν μεγαλύτερη πιθανότητα απελευθέρωσης γλουταμινικού οξέος σε σύγκριση με αυτές του διαφραγματικού ιππόκαμπου, καθώς οι Α1 υποδοχέων αδενοσίνης εντοπίζονται στην CA1 περιοχή κυρίως προσυναπτικά όπου ελέγχουν την απελευθέρωση γλουταμινικού οξέος. Στη συνέχεια της παρούσας μελέτης δείξαμε ότι η έκφραση του mRNA και των πρωτεϊνών για τις κυριότερες υπομονάδες του GABAA υποδοχέα είναι διαφορετική μεταξύ του διαφραγματικού και του κροταφικού ιπποκάμπου. Ειδικά, στην CA1 περιοχή του ιπποκάμπου η έκφραση των α1, β2 και γ2 υπομονάδων ήταν μικρότερη, ενώ αντίθετα η έκφραση των α2 και β1 υπομονάδων ήταν μεγαλύτερη στον κροταφικό ιπποκάμπο σε σύγκριση με τον διαφραγματικό ιππόκαμπο. Σύμφωνα με προηγούμενες μελέτες που αφορούν την συνέκφραση των υπομονάδων στο σύμπλοκο του GABAA υποδοχέα τα αποτελέσματα μας υποδηλώνουν ότι ο α1β2 υποτύπος του GABAA υποδοχέα επικρατεί στον διαφραγματικό ιππόκαμπο, ενώ ο α2β1 υπότυπος κυριαρχεί στον κροταφικό ιππόκαμπο. Η διαφορετική κατανομή των υποτύπων στους δυο πόλους του ιπποκάμπου που είναι εντονότερη στην CA1 περιοχή, μπορεί να επηρεάζει τις ιδιότητες του διαύλου (αγωγιμότητα, πλάτος και διάρκεια των IPSCs), δείχνοντας ότι οι υπότυποι του GABAA υποδοχέα που εντοπίζονται στον κροταφικό ιππόκαμπο έχουν μικρότερη ανασταλτική αποτελεσματικότητα, η οποία συμφωνεί με την μικρότερη GABAA-προερχόμενη αναστολή που έχει δειχθεί στην CA1 περιοχή του κροταφικού ιππόκαμπου. Επιπλέον θα μπορούσε να εξηγήσει την μεγαλύτερη επιρρέπεια του κροταφικού ιππόκαμπου στην επιληψία. Η χαμηλότερη έκφραση του mRNA για τις α4, β3 και δ υπομονάδες του GABAA υποδοχέα στην περιοχή της οδοντωτής έλικας του κροταφικού ιπποκάμπο υποδεικνύει ότι η έκφραση του α4β3δ υποτύπου είναι μικρότερη στον κροταφικό σε σύγκριση με τον διαφραγματικό ιππόκαμπο. Καθώς έχει δειχθεί ότι ο α4β3δ υπότυπος παίζει σημαντικό ρόλο στην τονική αναστολή στα κοκκιώδη κύτταρα της οδοντωτής έλικας, τα παραπάνω αποτέλεσμα μας πιθανώς σημαίνει ότι η τονική αναστολή είναι διαφορετική στους δυο πόλους του ιππόκαμπου. Η αύξηση της έκφρασης του mRNA της α5 υπομονάδας στην CA1 περιοχή του κροταφικού ιπποκάμπου μπορεί να επηρεάζει την ικανότητα για συναπτική βραχυ- και μακρο-χρόνια πλαστικότητα η οποία έχει βρεθεί να είναι διαφορετική μεταξύ του κροταφικού και του διαφραγματικού ιπποκάμπου καθώς έχει δειχθεί ότι οι α5-υπότυποι παίζουν ρόλο σε διαδικασίες μνήμης και μάθησης. Επίσης, οι α5-υπότυποι του GABAA υποδοχέα στην CA1 περιοχή του ιππόκαμπου συμμετέχουν στην τονική αναστολή. Τα υψηλότερα επίπεδα στην έκφραση του mRNA για την α5 υπομονάδα στον κροταφικό ιππόκαμπο σε σύγκριση με τον διαφραγματικό ιππόκαμπο πιθανώς υποδεικνύουν ότι η τονική αναστολή είναι διαφορετική στην CA1 περιοχή των δυο πόλων του ιππόκαμπου. Στο δεύτερο μέρος της παρούσας διατριβής μελετήσαμε την πιθανή συσχέτιση του GABAεργικού συστήματος με την οργάνωση των "in vitro" οξέων κυμάτων η οποία έχει παρατηρηθεί, σε κανονικές "in vitro" συνθήκες, μόνο σε τομές του κροταφικού ιππόκαμπου. Για το λόγο αυτό πραγματοποιήσαμε αναλυτική μελέτη της έκφρασης του mRNA των υπομονάδων (α1, α2, α5, β1, β2, β3, γ2) του GABAΑ υποδοχέα σε διάφορα χρονικά διαστήματα κατά την κανονική "in vitro" διατήρηση των τομών (15min, 1, 3, 5 και 8h). Αρχικά μελετήσαμε την έκφραση των πρώιμων γονιδίων (c-fos, zif-268), που είναι δείκτες της νευρωνικής ενεργότητας, μετά από 5 ώρες κανονικής "in vitro" διατήρησης των τομών με σκοπό τη πιθανή συχέτιση της έκφρασης τους με την οργάνωση των "in vitro" οξέων κυμάτων. Τα αποτελέσματα μας έδειξαν και στους δυο πόλους του ιπποκάμπου παρόμοια αύξηση της έκφρασης του mRNA τόσο για το c-fos όσο και για zif-268 γεγονός που υποδηλώνει ότι γονιδιακή ενεργότητα είναι παρόμοια και όσο αφορά τα συγκεκριμένα πρώιμα γονίδια ανεξάρτητη της ανάπτυξης των "in vitro" οξέων κυμάτων. Στην CA1 περιοχή του κροταφικού ιππόκαμπου παρατηρήθηκε σημαντική αύξηση της έκφρασης του mRNA των α1, β2 και γ2 υπομονάδων του GABAΑ υποδοχέα η οποία ξεκινάει την 1η ώρα, δηλαδή πριν την οργανωμένη εμφάνιση της αυθόρμητης δραστηριότητας, γίνεται μέγιστη στις 4 ώρες παραμονής των τομών σε Τεχνητό Εγκεφαλονωτιαίο Υγρό (ΤΕΝΥ) και συμβαδίζει χρονικά με την οργάνωση των "in vitro" οξέων κυμάτων. Δεν παρατηρήθηκαν σημαντικές αλλαγές σε τομές που προέρχονται από τον διαφραγματικό ιππόκαμπο. Έχει δειχθεί ότι οι α1-υπότυποι παίζουν σημαντικό ρόλο στην ανασταλτική ικανότητα του υποδοχέα. Επίσης η παρουσία της β2 υπομονάδας στον δίαυλο χαρακτηρίζει μεγαλύτερα σε πλάτος και διάρκεια ανασταλτικά ρεύματα συγκρινόμενη με τις β1 υπομονάδες. Φαίνεται λοιπόν ότι ο υπότυπος α1β2γ2, του οποίου η έκφραση αυξάνει πριν την έναρξη της οργανωμένης ρυθμικής δραστηριότητας, λόγω της συγκρότησης του από τις συγκεκριμένες υπομονάδες, έχει μεγάλη ανασταλτική αποτελεσματικότητα η οποία μπορεί να συμμετέχει στην ανάπτυξη των "in vitro" οξέων κυμάτων. Η δέσμευση της [3H]–muscimol αυξάνει σε τομές που προέρχονται μόνο από τον κροταφικό ιππόκαμπο και έχουν παραμείνει σε κανονικές "in vitro" συνθήκες για 8 ώρες σε σύγκριση με αντίστοιχες τομές που προέρχονται αμέσως μετά την θανάτωση του ζώου. Καμία αλλαγή δεν παρατηρήθηκε στην δέσμευση της [3H]–muscimol σε τομές που προέρχονται από τον διαφραγματικό ιππόκαμπο. Η αύξηση της δέσμευσης της [3H]–muscimol μόνο στις τομές που προέρχονται από τον κροταφικό ιππόκαμπο είναι σε συμφωνία με την αύξηση της έκφρασης του α1β2γ2-υποτύπου καθώς έχει δειχθεί ότι η θέση δέσμευσης της muscimol στο δίαυλο του GABAA υποδοχέα είναι μεταξύ των α1 και β2 υπομονάδων. Συμπερασματικά, η εκλεκτική αύξηση της έκφρασης του α1β2γ2-υπότυπου μόνο στην CA1 περιοχή του κροταφικού δηλώνει μεγαλύτερη ανασταλτική αποτελεσματικότητα των GABAA υποδοχέων, δεδομένου ότι ο α1β2γ2-υπότυπος προκαλεί μεγαλύτερα ανασταλτικά μετασυναπτικά ρεύματα. Το παραπάνω μπορεί να σχετίζεται με την "in vitro" εμφάνιση των οξέων κυμάτων καθώς η αυθόρμητη δραστηριότητα προέρχεται από GABAA-επαγόμενες υπερπολώσεις των πυραμιδικών κυττάρων, ενώ και η αύξηση στην έκφραση του α1β2γ2-υποτύπου συμπίπτει χρονικά με την εμφάνιση των "in vitro" οξέων κυμάτων. / The hippocampus in the rat appears grossly as an elongated structure with its long axis bending in a C-shaped manner from the septal nuclei rostrodorsally to the incipient temporal lobe caudoventrally. The long axis of the hippocampal formation is referred as the dorsoventral axis. Although hippocampus has been traditionally thought as a homogeneous structure, several studies have been demonstrated differences at several organization levels (from the behavioural to the cellular) between its dorsal (DH) and ventral (VH) pole. In the present study, we examined whether the recently reported differences in the GABA-mediated somatic inhibition between the DH and VH could be related to variations in the GABAA receptors. We therefore studied the quantitative distribution, the kinetic parameters and the subunit composition of the GABAA receptors in the two parts of hippocampus. We also studied the A1 adenosine receptors in order to examine the involvement of the adenosinergic system in the glutamate release between the two hippocampal poles. The study of [3H]-CHA binding on A1 adenosine receptors by using "in vitro" quantitative autoradiography, revealed a weaker A1 receptor binding in VH compared to DH in all regions we examined. Taken into consideration that the A1 adenosine receptors are localized in the CA1 glutamatergic terminals, these results may to some extend explain our hypothesis that synapses in the VH have greater probability of glutamate release compared to those in the DH counterpart. Recent data have demonstrated a weaker somatic GABAergic inhibition in CA1 region of VH compared to DH. We therefore examined possible differences in the GABAA receptor subunit composition and receptor binding parameters between DH and VH by using "in situ" hybridization, western blotting and the specific binding of the GABAA receptor agonist [3H]-muscimol using quantitative autoradiography and saturation experiments. The experiments demonstrated that the VH compared to DH displayed: 1) lower levels of mRNA expression for α1, β2, γ2 but higher levels for α2 and β1 subunits in CA1, CA2 and CA3, with the differences being more pronounced in CA1 region. Western blot analysis confirmed the mRNA expression data, showing lower levels for α1, β2 and higher levels for α2 subunits’ protein. Only in the CA1 region the mRNA levels of α5 were higher, while those of α4 subunit were slightly lower; in dentate gyrus, the mRNA levels of α4, β3 and δ subunits were significantly lower in VH compared to DH presumably suggesting a lower expression of the α4/β3/δ receptor subtype; 2) lower levels of [3H]-muscimol binding in the VH, with the lowest value observed in CA1, apparently resulting from weaker affinity for GABA and not from a decreased receptor density, since the KD values were higher in VH, while the Bmax values were similar between DH and VH. In conclusion, the differences in the subunit mRNA and protein expression and the lower affinity of GABAA receptor observed predominantly in CA1 region of VH, suggest that the α1 subunit-containing GABAA receptors dominate in the DH, while the α2 subunit-containing receptors prevail in VH. This could underlie the lower GABAA mediated somatic inhibition observed in VH and, to some extent, explain: a) the higher liability of VH for epileptic activity and b) the differential involvement of DH and VH in cognitive and emotional processes. Recent electrophysiological experiments have been shown that slices from the VH of adult rats generate rhythmical activity during their maintenance in the recording chamber. This activity is fully organized during the first 3 hours of in vitro maintenance and resembles the in vivo recorded hippocampal "sharp waves", therefore called "in vitro sharp waves". The field manifestation of this spontaneous activity results from GABAA receptor-mediated hyperpolarizations in pyramidal cells. The aim of the second part of the present thesis focused on the possible relationship between the characteristics of GABAA receptors and the development of "in vitro sharp waves". Using the "in situ hybridisation" technique, we examined the mRNA expression of the alpha1/2/5,beta1/2/3 and gamma2 subunits of GABAA receptor and the binding of GABAA receptor agonist [3H]-muscimol in a time course including periods before and during the development of the "in vitro sharp waves". Six sets of transversely cut DH and VH slices were prepared: slices frozen immediately after killing the animal (naive slices), and slices maintained in vitro and frozen at different time points (15min, 1, 3, 5 and 8h) during the electrophysiological experiment. The results showed: A) Upregulation of alpha1, beta2 and gamma2 subunits mRNA in VH but not in DH slices at 1h of their maintenance, which became significant at 3h as compared to the respective naive slices; B) Increase in [3H]-muscimol binding only in VH slices, obtained at 8h compared to the respective naive ones. The upregulation of the α1β2γ2 GABAA receptor subtype (starting at 1h) in VH but not in DH presumably suggests an increase in GABAergic activity, which could be related with the appearance of "in vitro sharp waves" observed only in VH; C) Τhe similar mRNA expression of the early genes c-fos and zif-268 in the two hippocampal poles showing a comparable general gene activity in DH and VH. In conclusion, the α1β2γ2 subtype dominates in DH while the α2β2-subtype prevails in VH and this could be related to the weaker somatic inhibition observed in the CA1 region of VH, and also to the distinct involvement of DH and VH in cognitive and emotional processes. Moreover, the higher expression of the GABAA receptor subtype α4β4δ in the DG of DH compared to VH may imply a higher tonic inhibition in the former hippocampal pole. The upregulation of the α1β2γ2- subtype only in VH slices during their in vitro maintenance may reflect an increase in the impact of GABAA receptor-mediated transmission, which is required for the organization of "in vitro" sharp waves.

γ-αμινοβουτιρικό οξύ

Υπομονάδες

573.86

Dorsal hippocampus

Ventral hippocampus

GABA

Subunits

Septal

Temporal

Rôle des neurones sérotoninergiques de la voie raphé-hippocampe ventral dans les comportements anxieux

Perreault, Félix

08 1900

Il y a longtemps qu’on a attribué à l’hippocampe un rôle central dans la mémoire, mais ce n’est pas son unique rôle. Un nombre grandissant d’études attestent que l’hippocampe peut être séparé en deux régions, dorsale et ventrale, qui sont fonctionnellement différentes. La partie dorsale de l’hippocampe est responsable du rôle classique dans la mémoire spatiale et contextuelle, alors que la région ventrale de l’hippocampe est importante dans l’expression de l’anxiété et de la motivation, entre autres. Les projections des noyaux du raphé, l’unique source d’afférences sérotoninergiques de l’hippocampe, auraient un rôle régulateur sur ses fonctions, dont le comportement anxieux. Toutefois, les fonctions de la projection sérotoninergique raphé-hippocampe ventral ne sont pas entièrement caractérisées et les différents rôles des sous-populations de neurones sérotoninergiques au sein même de la projection raphé-hippocampe ventral sont peu connus. Dans ce projet de recherche, nous avons utilisé des tests comportementaux et des outils optogénétiques, afin de déterminer le rôle de la projection sérotoninergique raphé-hippocampe ventral dans le comportement d’aversion. Notre hypothèse est que la sérotonine régule l’anxiété en agissant sur l’hippocampe ventral via cette projection. Nous démontrons entre autres que l’activation de la projection sérotoninergique raphé-hippocampe ventral induit une hausse de l’anxiété, mais spécifiquement chez les femelles. Nous démontrons aussi que l’activation de la projection réduit la locomotion. Nos données offrent un nouveau point de vue sur le rôle du raphé médian dans l’anxiété ainsi que sur l’importance du sexe dans l’expression du comportement anxieux. / It has been known for a long time that the hippocampus has a central role in memory, but it isn’t its sole function. A growing number of studies are showing that the hippocampus can be split in two regions, dorsal and ventral, that are functionally different. The dorsal part is responsible for the classic and well-known role of the hippocampus in spatial and contextual memory, while the ventral region is important for the expression of anxiety and motivation, among other roles. The only serotonergic input of the hippocampus are the raphe nuclei and it has been suggested that it has a regulatory effect over its functions, such as anxiety. Nonetheless, the functions of the raphe-ventral hippocampus serotonergic projection are not fully characterized and sub-populations of serotonergic neurons inside the projection itself aren’t known. In this research project, we used behavioral tests and optogenetic tools to determine whether the raphe to ventral hippocampus serotonergic projection is able to influence aversive behaviors. Our hypothesis is that serotonin regulates anxiety through its influence on the ventral hippocampus via the raphe-ventral hippocampus serotonergic projection. We found that optogenetic activation of the projection induces heightened anxiety, but only in female mice. Our data offer new insight as to how the median raphe regulates anxiety and the importance of sex in the expression of anxiety.

Anxiété

Sérotonine

Hippocampe ventral

Noyaux du raphé

Optogénétique

Anxiety

Serotonin

Ventral hippocampus

Raphe nuclei

Optogenetics

Implication des corticoïdes et de leurs récepteurs hippocampiques dans les effets rapides et différés du stress sur le rappel mnésique / Involvement of corticosteroids and their hippocampal receptors in fast and delayed effects of stress on memory retrieval.

Dorey, Rodolphe

06 June 2013

Tout d’abord, nous avons démontré l’origine périphérique de la corticostérone après l’administration d’un stress aigu. Pour cela, nous avons utilisé un modèle de souris déficient en transporteur de corticostérone : Corticosterone binding-globulin (Cbg-/-). Ensuite, nous avons déterminé si les effets rapides du stress sur le rappel mnésique dépendaient de mécanismes non-génomiques. Nous avons précisé si ces effets étaient médiés par les récepteurs aux minéralocorticoïdes (MR) ou aux glucocorticoïdes de l’hippocampe. Dans ce but dans un premier temps, nous avons injecté un complexe macromoléculaire de corticostérone (Cort-3CMO-BSA) qui ne franchit pas la membrane cellulaire pour évaluer l’implication de mécanismes membranaires. Dans un deuxième temps nous avons administré dans l’hippocampe dorsal (HD) ou ventral (HV), 15 minutes avant le stress, l’antagoniste MR (RU 28318) et l’antagoniste GR (RU 38486) et nous avons évalué les performances mnésiques à 15, 60, 105 et 120 minutes après le stress. En effet ces délais ont été choisis selon l’apparition de pics de corticostérone induit par le stress, mesurés par microdialyse, dans l’HD et l’HV.Les principaux résultats obtenus sont : i) les souris Cbg -/- ne présentent pas de déficit mnésique 15 min après l’administration d’un stress aigu, contrairement aux souris contrôles qui ont un déficit mnésique important; ii) De même, l’administration de métyrapone (un inhibiteur de synthèse de la corticostérone) prévient des effets rapides du stress sur la mémoire; iii) Nous avons démontré que les effets rapides délétères sont médiés par des récepteurs membranaires, puisque l’injection de Cort-3CMO-BSA dans l’HD produit des effets similaires au stress aigu. De plus, l’effet de l’injection du complexe Cort-3CMO-BSA n’est pas bloqué par l’injection systémique d’anisomycine (un inhibiteur de synthèse protéique) nous avons montré que les récepteurs membranaires aux glucocorticoïdes de type MR sont responsables des effets cognitifs rapides du stress et de la cort-3CMO-BSA sur le rappel mnésique ;iv) Dans l’HD, l’injection du RU 28318 bloquait les effets délétères du stress quand les performances mnésiques étaient évaluées 15 min après le stress, mais non aux délais plus longs. Au contraire, le RU 38486 prévenait les déficits mnésiques quand les performances étaient évaluées à 60 mais non à 105 min après le stress. Dans l’HV, le schéma opposé est observé puisque l’injection du RU 38486 est dénuée d’effet quand il est injecté à 60 min après le stress mais il bloque les déficits mnésiques induits 105 min après le stress. L’implication des récepteurs MR et GR et l’efficacité de leur antagoniste semble dépendant de l’évolution de la concentration de corticostérone au cours du temps dans l’HD et l’HV.Pour conclure, notre étude a mis en évidence que le stress aigu diminue le rappel mnésique hipocampo-dépendant par l’intermédiaire d’un mécanisme de “switch” impliquant les récepteurs MR puis GR de l’HD à des délais plus courts et ensuite seulement les récepteurs GR de l’HV à des délais plus long. / We first showed the peripheral origin of corticosterone after an acute stress administration (electric foot-shocks) using corticosterone binding globulin-deficient mice (Cbg -/-). Then, we intended to determine if the rapid effects of stress on memory retrieval depended on non-genomic mechanisms and in a further step to precise whether such effects are mediated by mineralocorticoid (MR) or glucocorticoid receptors (GR) in the hippocampus. To that aims, we first injected a macromolecular complex of corticosterone (Cort-3CMO-BSA) that cannot cross the cell membrane to assess the involvement of membrane mechanisms. In a second step, we injected 15 minutes before stress delivery either in the dorsal (DH) or ventral (VH) hippocampus the MR antagonist (RU 28318) and GR antagonist (RU 38486) and evaluated memory at 15, 60, 105 and 120 minutes after stress delivery. Indeed, these delays were chosen according to the occurrence of stress-induced corticosterone peaks measured by microdialysis in DH and VH.The main results obtained in this study are: i) Cbg -/- mice are not affected by stress delivery occurring 15 minutes before memory testing, in contrast wild-type control mice which exhibited an important memory retrieval deficit; ii) Similarly, the rapid effects of stress on memory could be prevented by the systemic injection of metyrapone (a corticosterone synthesis inhibitor); iii) We showed that the rapid (15min) deleterious of stress on memory are mediated by membrane receptors, since the injection of Cort-3CMO-BSA in the DH produced similar effects as stress delivery. Moreover, the effect of the Cort-3CMO-BSA complex is not blocked by systemic injection of anisomycin (a protein synthesis inhibitor); iv) In DH, the injection of RU 28318 blocked the deleterious effects of stress when testing occurred 15 min after stress but not for longer delays. In contrast, RU 38486 prevented memory retrieval impairments when performance was evaluated at 60 but not at 105 min after stress. In addition, the opposite pattern was observed in VH since RU 38486 was denied of any effects when injected at 60 min but blocked the stress-induced memory impairments at the 105 min post-stress delay. The involvement of MR and GR receptors and consequently the efficiency of their antagonists seem to depend on the time-course evolutions of stress-induced corticosterone rises within the DH and VH.In conclusion, our study evidenced that acute stress impairs hippocampus-dependent memory retrieval via a switch mechanism involving the MR then GR in DH at shorter delays and then only GR in VH at longer delay.

Stress aigu

Hippocampe dorsal et ventral

Microdialyse

Corticostérone

Rappel

Effets génomique et non génomique

Acute stress

Dorsal and ventral hippocampus

Microdialysis

Corticosterone

Retrieval

Genomic and non-genomic effects

Contribuição diferencial do hipocampo ventral e do complexo amidalóide na modulação de respostas defensivas inatas e condicionadas de camundongos

Amaral, Vanessa Cristiane de Santana [UNESP]

04 February 2011

Made available in DSpace on 2014-06-11T19:31:04Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-02-04Bitstream added on 2014-06-13T20:41:17Z : No. of bitstreams: 1 amaral_vcs_dr_arafo.pdf: 3128795 bytes, checksum: 3d66997069eddcbbbf04cf4e7e70700f (MD5) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Quando os animais são confrontados com estímulos ambientais ameaçadores como a exposição ao predador ou estímulos como altura, iluminação e estímulos nociceptivos, exibem reações de defesa coordenadas e específicas. Nas últimas décadas, observa-se um crescente interesse pela utilização de estímulos naturalísticos para o estudo das bases neurais de emoções como o medo e ansiedade. Nesse contexto, o teste de exposição ao rato (RET), um novo modelo etológico de interação presa-predador, utilizando camundongos (presa) e ratos (predador), foi desenvolvido para avaliar a expressão de diferentes comportamentos defensivos na presa. Entretanto, poucos estudos foram conduzidos com esse modelo no intuito de investigar as bases neurais das respostas defensivas de camundongos expostos ao rato. Adicionalmente, evidências da literatura destacam que o hipocampo ventral (HV) e o complexo amidalóide (CA) parecem contribuir diferencialmente na modulação de respostas defensivas frente a estímulos proximais (predador) ou potenciais. Assim, o presente estudo foi conduzido para investigar o papel do HV e do CA nas respostas defensivas de camundongos exibidas diante do predador (rato) e do contexto associado ao predador. Para tal, o presente estudo foi dividido em quatro etapas. Na primeira delas, investigamos se o estresse da exposição ao predador no RET altera a secreção de corticosterona em camundongos e determinamos a magnitude e a duração desta secreção. Na segunda etapa, avaliamos o papel do HV e do CA, através da injeção local do agonista de receptores GABAA muscimol (0,1 μg/0,1 μl), na mediação de respostas comportamentais defensivas de camundongos expostos ao RET (situação proximal) e comparamos com aquelas apresentadas durante a exposição ao labirinto em cruz elevado (LCE - situação potencial). Subsequentemente, investigamos se camundongos expostos... / When animals are confronted with environmental threatening situations such as exposure to a predator as well as to height, high illumination and nociceptive stimuli they exhibit defensive behaviors. Over the past decades there has been a growing interest by the neuroscientists in the use of naturalistic stimuli to the study of the neural systems of the emotions such as fear and anxiety. In this context, the Rat Exposure Test (RET) which is a new ethological model of prey-predator interaction using mice (prey) and rats (predator) was developed in order to evaluate the expression of different defensive behaviors in the prey. However few studies using this model have been carried out with the objective of investigating the neural systems of the defensive behaviors in mice exposed to rats. In addition, evidence in literature has shown that the ventral hippocampus (VH) and the amygdaloid complex (AC) contribute differentially in the modulation of defensive behaviors during exposure to either potential or immediate stimuli (predator). Thus, the present study was aimed at investigating the role of VH and AC in the modulation of defensive behaviors of mice when exposed to predators (rats) as well as the predatory context. The experiment comprised four parts: (i) to investigate both whether stress regarding the exposure to the predator alters the corticosterone secretion in mice and to determine the magnitude and the duration of this secretion; (ii) the role of VH and AC was evaluated through local microinjection of the GABAA receptor agonist muscimol (0,1 μg/0,1 μl) in the modulation of defensive behavioral responses of mice exposed to RET (proximal aversive situation). The responses then were compared to those presented during to the exposure to the elevated plus-maze (EPM - potential aversive situation); (iii) to investigate whether mice exposed to natural predator (rat) in RET exhibit... (Complete abstract click electronic access below)

Hipocampo (Cerebro)

Teste de exposição ao rato

Labirinto em cruz elevado

Hipocampo ventral

Rat exposure test

Elevated plus-maze

Ventral hippocampus

Amygdaloid complex

Defensive behaviors

Contextual fear conditioning

Estudo do envolvimento da via NMDA-NO do eixo dorso-ventral do hipocampo sobre o comportamento induzido pelo estresse de nado forçado / Involvement of the NMDA-NO pathway of the dorso/ventral hippocampal axis in the modulation of behavioral responses elicited by the forced swimming test

Cassiano Ricardo Alves Faria Diniz

31 January 2013

Acredita-se que diferenças hodológicas e diferente padrão de expressão gênica ao longo do eixo dorso/ventral do hipocampo seriam responsáveis pela distinta função entre a porção dorsal (HD) e ventral do mesmo (HV). HD seria responsável por processos cognitivos, tais como memória e aprendizagem espacial, e o HV pelas respostas neuroendócrinas e emocional-motivacionais ao estresse. No entanto, não há muitos estudos acerca de diferenças entre HD e HV na modulação de comportamentos relacionados à neurobiologia da depressão. Há, contudo, dados indicando que o bloqueio de receptores glutamatérgicos do tipo NMDA ou da síntese de NO no HD induz efeito semelhante ao dos antidepressivos (i.e. do tipo antidepressivo) no teste do nado forçado (TNF). Quanto ao HV, a função da neurotransmissão glutamatérgica/nitrérgica na neurobiologia da depressão permanece não investigado. Dessa forma, o objetivo do presente estudo foi realizar o bloqueio reversível do HD ou do HV, em diferentes momentos, em animais submetidos ao TNF. O próximo passo foi realizar a micro-injeção intra-HD ou intraHV do antagonista NMDA AP-7 ou do inibidor da óxido nítrico sintase neuronal (nNOS), N-PLA, ou do inibidor da guanilato ciclase solúvel (sGC), ODQ. Os resultados mostram que o bloqueio do HD ou do HV com cloreto de cobalto (CoCl2, bloqueador da neurotransmissão sináptica dependente de cálcio) não modificou o comportamento dos animais no TNF. No entanto a administração de AP-7 ou N-PLA ou ODQ no HV antes do teste, reduziu o tempo de imobilidade no TNF. Por outro lado, a injeção dessas drogas no HD foi capaz de reduzir o tempo de imobilidade quando administradas tanto depois do pré-teste quanto antes do teste. Estes resultados sugerem que as vias NMDA-NO do HD e do HV, estariam envolvidas na modulação da resposta comportamental frente ao estresse do nado forçado. Além disso, os dados indicam que a participação dessas estruturas é importante em diferentes momentos após a exposição ao estresse. / It is believed that hodological and genetic pattern of expression differences along dorsal/ventral hippocampal axis would be responsible for distinct functions attributed to its dorsal (DH) and ventral (VH) poles. DH would be responsible for cognitive process, such as spatial memory and learning, whereas the VH would be responsible for neuroendocrine and emotional-motivation responses to stress. However, there is no many studies about possible differences between DH and VH in the modulation of behavioral responses related to the neurobiology of depression. Though, there are data showing that the blockade of glutamatergic NMDA receptors blockers or NO synthesis inhibition within the DH induces similar effect to that of antidepressant drugs (like antidepressant effect) in the forced swimming test (FST). On the VH, The role of the glutamatergic/nitrergic neurotransmission remains to be investigated. Thus, the aim of this work was to perform the reversible blockade of DH or VH, at different times, in animals subjected to FST. Additionally, the next step was to perform a microinjections into the DH or the VH of NMDA antagonist (AP-7), inhibitor of neuronal nitric oxide synthase (nNOS, N-PLA), or the inhibitor of soluble guanylate cyclase (sGC, ODQ). The results show that blocking the VH or the DH (cobalt chloride, calcium dependent neurotransmission inhibitor) did not modify the behavior of animals during the TNF. However administration of AP-7, N-PLA or ODQ intra-HV, before testing, caused antidepressant-like effects. Moreover, injection of such drugs, intra-HD, was able to induce similar results when administered both after the pre-test and before testing. These results suggest that NMDA-NO pathway of both VH and DH is involved in the modulation of emotional responses to the forced swim stress, although there may be an interest differential participation of these structures at different times after exposure to stress.

Hipocampo dorsal e ventral

Óxido nítrico

Receptor glutamatérgico NMDA

Teste do nado forçado

Dorsal and ventral hippocampus

Forced swimming test

Glutamatergic NMDA receptor

Nitric oxide

Estudo do envolvimento da via NMDA-NO do eixo dorso-ventral do hipocampo sobre o comportamento induzido pelo estresse de nado forçado / Involvement of the NMDA-NO pathway of the dorso/ventral hippocampal axis in the modulation of behavioral responses elicited by the forced swimming test

Diniz, Cassiano Ricardo Alves Faria

31 January 2013

Acredita-se que diferenças hodológicas e diferente padrão de expressão gênica ao longo do eixo dorso/ventral do hipocampo seriam responsáveis pela distinta função entre a porção dorsal (HD) e ventral do mesmo (HV). HD seria responsável por processos cognitivos, tais como memória e aprendizagem espacial, e o HV pelas respostas neuroendócrinas e emocional-motivacionais ao estresse. No entanto, não há muitos estudos acerca de diferenças entre HD e HV na modulação de comportamentos relacionados à neurobiologia da depressão. Há, contudo, dados indicando que o bloqueio de receptores glutamatérgicos do tipo NMDA ou da síntese de NO no HD induz efeito semelhante ao dos antidepressivos (i.e. do tipo antidepressivo) no teste do nado forçado (TNF). Quanto ao HV, a função da neurotransmissão glutamatérgica/nitrérgica na neurobiologia da depressão permanece não investigado. Dessa forma, o objetivo do presente estudo foi realizar o bloqueio reversível do HD ou do HV, em diferentes momentos, em animais submetidos ao TNF. O próximo passo foi realizar a micro-injeção intra-HD ou intraHV do antagonista NMDA AP-7 ou do inibidor da óxido nítrico sintase neuronal (nNOS), N-PLA, ou do inibidor da guanilato ciclase solúvel (sGC), ODQ. Os resultados mostram que o bloqueio do HD ou do HV com cloreto de cobalto (CoCl2, bloqueador da neurotransmissão sináptica dependente de cálcio) não modificou o comportamento dos animais no TNF. No entanto a administração de AP-7 ou N-PLA ou ODQ no HV antes do teste, reduziu o tempo de imobilidade no TNF. Por outro lado, a injeção dessas drogas no HD foi capaz de reduzir o tempo de imobilidade quando administradas tanto depois do pré-teste quanto antes do teste. Estes resultados sugerem que as vias NMDA-NO do HD e do HV, estariam envolvidas na modulação da resposta comportamental frente ao estresse do nado forçado. Além disso, os dados indicam que a participação dessas estruturas é importante em diferentes momentos após a exposição ao estresse. / It is believed that hodological and genetic pattern of expression differences along dorsal/ventral hippocampal axis would be responsible for distinct functions attributed to its dorsal (DH) and ventral (VH) poles. DH would be responsible for cognitive process, such as spatial memory and learning, whereas the VH would be responsible for neuroendocrine and emotional-motivation responses to stress. However, there is no many studies about possible differences between DH and VH in the modulation of behavioral responses related to the neurobiology of depression. Though, there are data showing that the blockade of glutamatergic NMDA receptors blockers or NO synthesis inhibition within the DH induces similar effect to that of antidepressant drugs (like antidepressant effect) in the forced swimming test (FST). On the VH, The role of the glutamatergic/nitrergic neurotransmission remains to be investigated. Thus, the aim of this work was to perform the reversible blockade of DH or VH, at different times, in animals subjected to FST. Additionally, the next step was to perform a microinjections into the DH or the VH of NMDA antagonist (AP-7), inhibitor of neuronal nitric oxide synthase (nNOS, N-PLA), or the inhibitor of soluble guanylate cyclase (sGC, ODQ). The results show that blocking the VH or the DH (cobalt chloride, calcium dependent neurotransmission inhibitor) did not modify the behavior of animals during the TNF. However administration of AP-7, N-PLA or ODQ intra-HV, before testing, caused antidepressant-like effects. Moreover, injection of such drugs, intra-HD, was able to induce similar results when administered both after the pre-test and before testing. These results suggest that NMDA-NO pathway of both VH and DH is involved in the modulation of emotional responses to the forced swim stress, although there may be an interest differential participation of these structures at different times after exposure to stress.

Dorsal and ventral hippocampus

Forced swimming test

Glutamatergic NMDA receptor

Hipocampo dorsal e ventral

Nitric oxide

Óxido nítrico

Receptor glutamatérgico NMDA

Teste do nado forçado