Rôle de la neurogenèse hippocampique adulte dans la stabilisation à long terme de la mémoire spatiale / Role of adult hippocampal neurogenesis in spatial memory stabilization

Lods, Marie

06 December 2018

La neurogenèse hippocampique adulte fait référence à la création de neurones durant la vie adulte dans le gyrus denté de l’hippocampe. Une décennie de recherche a démontré l’importance de cette neurogenèse chez l’adulte dans les processus de mémoire. En particulier, la neurogenèse adulte est nécessaire à l’apprentissage spatial et l’apprentissage spatial lui-même augmente la survie et accélère le développement d’une population de nouveaux neurones immatures. Cependant, l’implication de ces nouveaux neurones « sélectionnés » par l’apprentissage dans le devenir de la mémoire reste incertaine. En conséquence, le travail de cette thèse porte sur l’étude du rôle de ces nouveaux neurones dans les processus de mémoire spatiale à long terme résultants de l’apprentissage d’origine, comme la restitution et la reconsolidation de la mémoire. En effet depuis plus d’un siècle, on sait qu’un apprentissage n’induit pas immédiatement une mémoire stable. Les souvenirs sont tout d’abord fragiles, puis vont au fil du temps devenir stables et insensibles aux perturbations via un processus appelé «consolidation de la mémoire». Cependant ce processus n’est pas immuable ; les souvenirs établis peuvent à nouveau devenir labiles lorsqu'ils sont rappelés ou réactivés lors d’une restitution de la mémoire. Cette déstabilisation d’une mémoire consolidée nécessite alors un nouveau processus de stabilisation appelé « reconsolidation de la mémoire ». Depuis sa découverte, la reconsolidation a vivement intéressé le milieu de la recherche sur la mémoire et un nombre croissant d’études a cherché à comprendre les mécanismes sous-tendant cette reconsolidation, en particulier dans l'hippocampe. Étonnamment, le processus de reconsolidation n’a été que très peu envisagé dans le contexte de la neurogenèse hippocampique adulte.Nous avons tout d’abord mis au point un protocole de reconsolidation de la mémoire spatiale du rat dans le labyrinthe aquatique de Morris. Cela nous a permis de montrer que les néo-neurones nés avant l’apprentissage étaient activés lors de la reconsolidation de la mémoire spatiale, ce qui n’est pas le cas des neurones issus du développement précoce. Afin de pouvoir établir une relation de causalité entre néo-neurones et processus de reconsolidation, nous avons ensuite développé un outil basé sur la technique pharmacogénétique des DREADDs (Designer Receptors Exclusively Activated by Designer Drugs) couplés à un rétrovirus. Cet outil permet de marquer les néo-neurones à leur naissance et de les manipuler (inhiber ou stimuler l’activation) plus tard, lors des processus de mémoire à long terme. Nous avons observé que les néo-neurones immatures modifiés par l’apprentissage étaient non seulement activés par la reconsolidation mais également nécessaire à celle-ci, à l’inverse des néo-neurones matures au moment de l’apprentissage. Nous avons enfin montré que stimuler l’activité des néo-neurones au moment de la restitution de la mémoire améliorait les performances des rats dans le labyrinthe aquatique.Ensemble, ces résultats de thèse soulignent le rôle critique de la neurogenèse hippocampique adulte dans la stabilisation de la mémoire spatiale à long terme. / Adult hippocampal neurogenesis refers to the creation of neurons during adult life in the dentate gyrus of the hippocampus. A decade of research has demonstrated the importance of this adult neurogenesis in memory processes. In particular, adult neurogenesis is necessary for spatial learning and spatial learning itself increases survival and accelerates the development of a population of new immature neurons. However, the involvement of these new modified / promoted / amplified / selected neurons by learning in the fate of memory remains unclear. The work of this thesis focuses on the study of the role of these new neurons in the long-term spatial memory processes resulting from the original learning, such as retrieval and reconsolidation.For more than a century, we know that learning does not immediately induce a stable memory. Memories are fragile at first and then become stable and insensitive to interferences over time, through a process called “memory consolidation". However this process is not immutable; the established memories can become labile again when they are reactivated during memory recall. This destabilization of a consolidated memory requires then a new stabilization process called "memory reconsolidation". Since its discovery, the reconsolidation process has strongly interested the memory research community and a growing number of studies have sought to understand the mechanisms underlying this reconsolidation, particularly in the hippocampus. Surprisingly, the process of reconsolidation has rarely been considered in the context of adult hippocampal neurogenesis.We first developed a protocol for memory reconsolidation of spatial memory in the Morris water maze in rats. This allowed us to show that new neurons born before learning were activated during reconsolidation of spatial memory, which is not the case of the neurons generated during the early development. In order to establish a causal relationship between new neurons and reconsolidation, we developed a tool based on the pharmacogenetic technique of DREADDs (Designer Receptors Exclusively Activated by Designer Drugs) coupled with a retrovirus. This tool is used to tag new neurons at their birth and manipulate them (inhibit or stimulate their activation) later during long-term memory processes. We observed that the population of neurons that were immature at the time of learning are not only activated by but also necessary for reconsolidation, unlike new neurons that were mature at the time of learning. We have finally shown that stimulating the activity of new neurons during retrieval improves the performance of rats in the water maze.All together, these thesis results highlight the critical role of adult hippocampal neurogenesis in long-term spatial memory stabilization.

Neurogenèse adulte

Reconsolidation de la mémoire spatiale

Piscine de Morris

Dreadds

Adult neurogenesis

Spatial memory reconsolidation

Morris watermaze

Dreadds

Cortical Influences on Cognitive and Respiratory Dysfunction in a Mouse Model of Rett Syndrome

Howell, Cody James

23 May 2019

No description available.

Neurobiology

Neurosciences

Rett syndrome

mPFC

Ketamine

DREADDs

Autism Spectrum Disorders

Effects of Aging and Corticofugal Modulation on Startle Behavior and Auditory Physiology

Marisa A Dowling (6689462)

10 June 2019

Frequency-modulated (FM) sweeps play a key role in species specific communication. Evidence from previous studies have shown that central auditory processing has been shown to vary based on the language spoken, which leads to the idea of experience-driven pitch encoding. Other studies have also shown that there is a decrease in this pitch encoding with aging. Using both iterated rippled noise (IRN) and frequency modulated amplitude modulation (FM/AM) methods to create complex pitch sweeps mimicking speech, allows for the processing of pitch to be determined. Neuromodulation using pharmacogenetics allows for the targeted inhibition of a specific neural pathway. Based on previous studies, the primary auditory cortex to inferior colliculus (A1/IC) pathway is hypothesized to be important in pitch encoding. However, there is a lack of evidence on specifically how the pitch information is encoded in the auditory system and how aging impacts the processing. To solve these issues, age-related changes in pitch encoding and maintaining pitch encoding through neuromodulation were characterized in the using behavioral and electrophysiology methods. Behavioral discrimination abilities, measured by modulation of the acoustic startle response, between pitch sweep direction and pitch sweep creation methods highlighted a reduced discrimination in aging and A1/IC inhibited rats. Electrophysiology changes was assessed using envelope-following responses (EFRs) and suggested a decreased initial frequency locking in aging and decrease in frequency locking overall with A1/IC pathway inhibition. Comparison of behavioral and electrophysiology to IRN and FM/AM stimuli show that the decrease in age-related processing as well as A1/IC pathway processing is larger in the behavioral pitch sweep discrimination than in the reduction in EFRs.

auditory neuroscience

auditory

DREADDs

inferior colliculus

auditory cortex

Chemogenetic Inhibition Of The Inferior Colliculus: Effects On Electrophysiology And Behavior

Nanami L. Miyazaki (5930753)

03 January 2019

Age-related hearing loss (ARHL) or presbycusis has grown to be a prevalent problem among the increasing aging population over the past century. Efficacy of hearing aids, cochlear implants or auditory brainstem implants have been shown, but with variable performance among patients, a fuller understanding of the complex circuitry of the auditory system would be beneficial for improving upon current technology as well as developing alternative treatments. In the current study, chemogenetics or DREADDs was utilized to inhibit the neuronal activity of the pathway between the medial geniculate body and the inferior colliculus. Subsequent effects of chemogenetic inhibition was assessed with electrophysiological measures– including auditory evoked potential recordings and single-unit recordings–as well as behavioral measures using the acoustic startle response and prepulse inhibition paradigm.

Neuroscience

auditory neuroscience

auditory

DREADDs

inhibition

inferior colliculuc

medial geniculate body

The role of the medial prefrontal cortex in delay discounting

Beckwith, Steven Wesley

January 2017

Indiana University-Purdue University Indianapolis (IUPUI) / Increased delay discounting (DD) has been associated with and is theorized to contribute to alcoholism and substance abuse. It is also been associated with numerous other mental disorders and is believed to be a trans-disease process (i.e., a process that occurs in and contributes to multiple different pathologies). Consequently insights gained from studying DD are likely to apply to many different diseases. Studies on the neurobiological underpinnings of DD have two main interpretations. The first interpretation is that two different neurobehavioral systems exist, one favoring delayed rewards (executive system) and one favoring immediate rewards (impulsive system), and the system with the greater relative activation determines choice made by an individual. Alternatively, a single valuation system may exist. This system integrates different information about outcomes and generates a value signal that then guides decision making. Preclinical investigations have steered clear of these two different interpretations and rather focused on the role of individual structures in DD. One such structure, the rat mPFC, may generate an outcome representation of delayed rewards that is critically involved in attributing value to delayed rewards. Moreover, there is evidence indicating the rat mPFC may correspond to the primate dlPFC, an executive system structure. The current body of work set about testing the hypotheses that the mPFC is necessary for attributing value to delayed rewards and that decreasing the activity in an executive system area, and thus the executive system, shifts inter-temporal preference towards immediate rewards. To this end the rat mPFC was inactivated using an hM4Di inhibitory designer receptor exclusively activated by designer drugs (DREADD; experiment 1) or microinjections of tetrodotoxin (TTX; experiment 2) while animals completed an adjusting amount DD task. Activation of the hM4Di inhibitory DREADD receptor caused a decrease in DD, opposite of what was predicted. Electrophysiological recordings revealed a subpopulation of neurons actually increased their firing in response to hM4Di receptor activation, potentially explaining the unpredicted results. Microinjections of TTX to completely silence neural activity in the mPFC failed to produce a change in DD. Together both results indicate that mPFC activity is capable of manipulating but is not necessary for DD and the attribution of value to the delayed reward. Consequently, a secondary role for the rat mPFC in DD is proposed in line with single valuation system accounts of DD. Further investigations determining the primary structures responsible for sustaining delayed reward valuation and how manipulating the mPFC may be a means to decrease DD are warranted, and continued investigation that delineates the neurobiological processes of delayed reward valuation may provide valuable insight to both addiction and psychopathology.

Prefrontal Cortex

Rat

Delay Discounting

Inter-temporal Choice

DREADDs

Tetrodotoxin

Impulsivity

Using chemogenetics and novel tools to uncover neural circuit and behavioral changes after spinal cord injury

Eisdorfer, Jaclyn, 0000-0003-3285-3473

January 2021

Spinal cord injury (SCI) results in persistent neurological deficits and significant long-term disability. Stimulation of peripheral afferents by epidural electrical stimulation (EES) has been reported to reduce spasticity by reorganizing spared and disrupted descending pathways and local circuits. However, a current barrier to the field is that the plasticity mechanisms that underly improved recovery is unknown. Using the power of hM3Dq Designer Receptors Exclusively Activated by Designer Drugs (DREADDs), we aim to accelerate the dissection of the mechanisms underlying enhanced recovery. In these studies, we identified the effect of clozapine-N-oxide (CNO) on the H-reflex of naïve animals; investigated the baseline influence of hM3Dq DREADDs in peripheral afferents in the intact animal using a novel behavioral tool, an addition of angled rungs to the horizontal ladder walking task; and began to uncover the neural and behavioral changes that accompany hM3Dq DREADDs activation in peripheral afferents after SCI. We observed no significant differences in the H-reflex with 4 mg/kg dosage of CNO administration (pre-CNO vs. CNO-active: p=0.82; CNO-active vs. CNO wash-out: p=0.98; n=6). On our novel ladder, we found significant differences in correct hind paw placement (p=0.0002, n=7) and incorrect placement (p=0.01) when DREADDs were activated with CNO (4 mg/kg). In our SCI study, we report that acute and chronic DREADDs activation may activate extensor muscles about the hip (32 cm/s: p=0.047; controls: n=6; DREADDs: n=8 and hereafter unless otherwise stated) as well as induce sprouting and synaptogenesis within motor pools and Clarke’s column in the lumbar spinal cord (motor pool: p=0.00053; Clarke’s column: p=0.021; controls: n=4; DREADDs: n=6). This muscle recruitment may have long-term effects such as increased hindquarter heights (e.g., 16 cm/s: p=0.017) and more frequent hindlimb coordination (p=0.002). Results from this study suggest hM3Dq DREADDs may have the potential to recapitulate EES-activation of afferents as well as provide a platform with which to functionally map changes that occur both within targeted afferents and second order neurons they effect. Future work, such as using C-Fos to examine and map changes in interneuronal networks, could seek to more directly tie changes in kinematics to observed changes in plasticity. / Bioengineering

Bioengineering

Neurosciences

Engineering

Chemogenetics

Dreadds

Epidural electrical stimulation

Hreflex

Sci

Spinal cord injury