Storage, recall, and novelty detection of sequences by the hippocampus: Elaborating on the SOCRATIC model to account for normal and aberrant effects of dopamine

ABSTRACT: In order to understand how the molecular or cellular defects that underlie a disease of the nervous system lead to the observ-able symptoms, it is necessary to develop a large-scale neural model. Such a model must specify how specific molecular processes contribute to neuronal function, how neurons contribute to network function, and how networks interact to produce behavior. This is a challenging undertaking, but some limited progress has been made in understanding the memory functions of the hippocampus with this degree of detail. There is increas-ing evidence that the hippocampus has a special role in the learning of sequences and the linkage of specific memories to context. In the first part of this paper, we review a model (the SOCRATIC model) that describes how the dentate and CA3 hippocampal regions could store and recall memory sequences in context. A major line of evidence for sequence recall is the “phase precession ” of hippocampal place cells. In the second part of the paper, we review the evidence for theta-gamma phase coding

The malleable brain: plasticity of neural circuits and behavior: A review from students to students

One of the most intriguing features of the brain is its ability to be malleable, allowing it to adapt continually to changes in the environment. Specific neuronal activity patterns drive long-lasting increases or decreases in the strength of synaptic connections, referred to as long-term potentiation (LTP) and long-term depression (LTD) respectively. Such phenomena have been described in a variety of model organisms, which are used to study molecular, structural, and functional aspects of synaptic plasticity. This review originated from the first International Society for Neurochemistry (ISN) and Journal of Neurochemistry (JNC) Flagship School held in Alpbach, Austria (Sep 2016), and will use its curriculum and discussions as a framework to review some of the current knowledge in the field of synaptic plasticity. First, we describe the role of plasticity during development and the persistent changes of neural circuitry occurring when sensory input is altered during critical developmental stages. We then outline the signaling cascades resulting in the synthesis of new plasticity-related proteins, which ultimately enable sustained changes in synaptic strength. Going beyond the traditional understanding of synaptic plasticity conceptualized by LTP and LTD, we discuss system-wide modifications and recently unveiled homeostatic mechanisms, such as synaptic scaling. Finally, we describe the neural circuits and synaptic plasticity mechanisms driving associative memory and motor learning. Evidence summarized in this review provides a current view of synaptic plasticity in its various forms, offers new insights into the underlying mechanisms and behavioral relevance, and provides directions for future research in the field of synaptic plasticity.Fil: Schaefer, Natascha. University of Wuerzburg; AlemaniaFil: Rotermund, Carola. University of Tuebingen; AlemaniaFil: Blumrich, Eva Maria. Universitat Bremen; AlemaniaFil: Lourenco, Mychael V.. Universidade Federal do Rio de Janeiro; BrasilFil: Joshi, Pooja. Robert Debre Hospital; FranciaFil: Hegemann, Regina U.. University of Otago; Nueva ZelandaFil: Jamwal, Sumit. ISF College of Pharmacy; IndiaFil: Ali, Nilufar. Augusta University; Estados UnidosFil: García Romero, Ezra Michelet. Universidad Veracruzana; MéxicoFil: Sharma, Sorabh. Birla Institute of Technology and Science; IndiaFil: Ghosh, Shampa. Indian Council of Medical Research; IndiaFil: Sinha, Jitendra K.. Indian Council of Medical Research; IndiaFil: Loke, Hannah. Hudson Institute of Medical Research; AustraliaFil: Jain, Vishal. Defence Institute of Physiology and Allied Sciences; IndiaFil: Lepeta, Katarzyna. Polish Academy of Sciences; ArgentinaFil: Salamian, Ahmad. Polish Academy of Sciences; ArgentinaFil: Sharma, Mahima. Polish Academy of Sciences; ArgentinaFil: Golpich, Mojtaba. University Kebangsaan Malaysia Medical Centre; MalasiaFil: Nawrotek, Katarzyna. University Of Lodz; ArgentinaFil: Paid, Ramesh K.. Indian Institute of Chemical Biology; IndiaFil: Shahidzadeh, Sheila M.. Syracuse University; Estados UnidosFil: Piermartiri, Tetsade. Universidade Federal de Santa Catarina; BrasilFil: Amini, Elham. University Kebangsaan Malaysia Medical Centre; MalasiaFil: Pastor, Verónica. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay. Instituto de Biología Celular y Neurociencia ; ArgentinaFil: Wilson, Yvette. University of Melbourne; AustraliaFil: Adeniyi, Philip A.. Afe Babalola University; NigeriaFil: Datusalia, Ashok K.. National Brain Research Centre; IndiaFil: Vafadari, Benham. Polish Academy of Sciences; ArgentinaFil: Saini, Vedangana. University of Nebraska; Estados UnidosFil: Suárez Pozos, Edna. Instituto Politécnico Nacional; MéxicoFil: Kushwah, Neetu. Defence Institute of Physiology and Allied Sciences; IndiaFil: Fontanet, Paula. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay. Instituto de Biología Celular y Neurociencia ; ArgentinaFil: Turner, Anthony J.. University of Leeds; Reino Unid

What is memory? The present state of the engram

The mechanism of memory remains one of the great unsolved problems of biology. Grappling with the question more than a hundred years ago, the German zoologist Richard Semon formulated the concept of the engram, lasting connections in the brain that result from simultaneous "excitations", whose precise physical nature and consequences were out of reach of the biology of his day. Neuroscientists now have the knowledge and tools to tackle this question, however, and this Forum brings together leading contemporary views on the mechanisms of memory and what the engram means today

Dopaminergic modulation of synaptic transmission and plasticity in the lateral amygdala

Fear conditioning is one of the most powerful and widely used paradigm to investigate the mechanisms of associative learning in animals (LeDoux, 2000; Maren, 2001). Behavioral and in vivo electrophysiological evidence indicate that induction of long-term-potentiation (LTP), a form of associative, activity-dependent synaptic plasticity in the lateral amygdala (LA), a brain structure tightly controlled by GABAergic inhibition, underlies the acquisition of fear conditioning (Lang and Pare, 1997; Pare et al., 2003). Dopamine (DA), the most abundant catecholemine in the brain, is released in the amygdala upon stress. DA receptor activation is required for the potentiation of sensory evoked neuronal activity in the LA during conditioning (Rosenkranz and Grace, 2002). Conversely, intra-amygdala injections of DA receptor antagonists prevents the acquisition of fear conditioning (Greba et al., 2001; Greba and Kokkinidis, 2000; Guarraci et al., 2000; Guarraci et al., 1999). The cellular and synaptic mechanisms underlying the dopaminergic modulation of fear conditioning and synaptic plasticity are, however, still unknown. In the first part of my work, I showed that DA gates the induction of LTP in the mouse LA by supressing feed-forward inhibition mediated by local interneurons. The action of DA on synaptic plasticity depended on the activation of D2 receptors and appeared to be twofold. First, it reduced the quantal content at inhibitory synapses, thereby decreasing inhibitory synaptic transmission and second, it facilitated inhibition onto interneurons by depolarizing interneurons involved in disinhibition. In the second part of my work I investigated the role of DA on spontaneous inhibitory network activity. Consistent with previous in vivo data showing that systemic administration of DA agonists in the LA increases the spontaneous firing of interneurons (Rosenkranz and Grace, 1999), we found that bath application of DA increased the frequency of spontaneous inhibitory transmission recorded from projection neurons. In contrast to the gating of LTP, this effect required the activation of D1 and D2 receptors in synergy. Preliminary data suggested that the D1 receptor-mediated increase in spontaneous inhibitory transmission did not involve cAMP-mediated intracellular signaling mechanisms

Characterization of Ambra1 heterozygous mice as genetic mouse model of female-specific autism

Autism is known as a heritable neurodevelopmental disorder, diagnosed prior to the age of three years in humans based on three major domains: (1) impairment in social interaction (2) communication deficits (3) restricted interests and repetitive behaviors. Since it is a very heterogeneous disorder with various causes and different combinations of phenotypes, it is also called autism spectrum disorder (ASD). Monogenic heritable forms of ASD enable us to develop genetic mouse models of autism in order to obtain mechanistic insight in this disorder. Ambra1 is a positive regulator of Beclin1, a major player in the formation of autophagosomes during the process of autophagy. While Ambra1 null mutation leads to embryonic lethality, we could show that Ambra1 heterozygous mice (Ambra1+/-) display autism-like behavior only in females. Purpose of this thesis was therefore to characterize this mouse line further. It turned out that communication deficits, measured by ultrasound vocalization, start in the neonatal stage of females, while physical or neurological development is normal in Ambra1+/-. Female Ambra1 mutants had a stronger reduction in Ambra1 expression than male mutants, which gives first hints of the female-specific autism-like behavior in this mouse line. Mild enlargement of whole brain and hippocampus was detected in both Ambra1+/- males and females, with no change of ventricle size. Since β-galactosidase, used as reporter expressed under the Ambra1 promoter, was found only in neuronal cells, I focused on understanding the neural mechanism of its phenotype. Short-term and long-term synaptic plasticity in the hippocampus was normal for males and females of both genotypes. However, the power of gamma oscillations (γ-power), indicative of change in the balance of excitation and inhibition, was age-dependently altered in Ambra1+/- females only. However, this difference was not detected in male. Moreover, increased susceptibility to seizures, a known comorbid condition of ASD was restricted to females, suggesting an association between autism-like behavior, gamma oscillation and seizure propensity in female Ambra1+/- mice. Next, I approached the neuronal substrate of these three phenotypes by morphological analysis of hippocampal pyramidal neurons, such as dendritic arborization and synapse number. A genotype-associated difference of dendritic arborization was detected in neither males nor females. The quantification of spines or synapses and cellular electrophysiology are still on-going. First signals point to an imbalance between excitation and inhibition as a cause of the female autism-like behavior in Ambra1+/- mice

Characterization of Ambra1 heterozygous mice as genetic mouse model of female-specific autism

Autism is known as a heritable neurodevelopmental disorder, diagnosed prior to the age of three years in humans based on three major domains: (1) impairment in social interaction (2) communication deficits (3) restricted interests and repetitive behaviors. Since it is a very heterogeneous disorder with various causes and different combinations of phenotypes, it is also called autism spectrum disorder (ASD). Monogenic heritable forms of ASD enable us to develop genetic mouse models of autism in order to obtain mechanistic insight in this disorder. Ambra1 is a positive regulator of Beclin1, a major player in the formation of autophagosomes during the process of autophagy. While Ambra1 null mutation leads to embryonic lethality, we could show that Ambra1 heterozygous mice (Ambra1+/-) display autism-like behavior only in females. Purpose of this thesis was therefore to characterize this mouse line further. It turned out that communication deficits, measured by ultrasound vocalization, start in the neonatal stage of females, while physical or neurological development is normal in Ambra1+/-. Female Ambra1 mutants had a stronger reduction in Ambra1 expression than male mutants, which gives first hints of the female-specific autism-like behavior in this mouse line. Mild enlargement of whole brain and hippocampus was detected in both Ambra1+/- males and females, with no change of ventricle size. Since β-galactosidase, used as reporter expressed under the Ambra1 promoter, was found only in neuronal cells, I focused on understanding the neural mechanism of its phenotype. Short-term and long-term synaptic plasticity in the hippocampus was normal for males and females of both genotypes. However, the power of gamma oscillations (γ-power), indicative of change in the balance of excitation and inhibition, was age-dependently altered in Ambra1+/- females only. However, this difference was not detected in male. Moreover, increased susceptibility to seizures, a known comorbid condition of ASD was restricted to females, suggesting an association between autism-like behavior, gamma oscillation and seizure propensity in female Ambra1+/- mice. Next, I approached the neuronal substrate of these three phenotypes by morphological analysis of hippocampal pyramidal neurons, such as dendritic arborization and synapse number. A genotype-associated difference of dendritic arborization was detected in neither males nor females. The quantification of spines or synapses and cellular electrophysiology are still on-going. First signals point to an imbalance between excitation and inhibition as a cause of the female autism-like behavior in Ambra1+/- mice

Spike Timing Dependent Plasticity: A Consequence of More Fundamental Learning Rules

Spike timing dependent plasticity (STDP) is a phenomenon in which the precise timing of spikes affects the sign and magnitude of changes in synaptic strength. STDP is often interpreted as the comprehensive learning rule for a synapse – the “first law” of synaptic plasticity. This interpretation is made explicit in theoretical models in which the total plasticity produced by complex spike patterns results from a superposition of the effects of all spike pairs. Although such models are appealing for their simplicity, they can fail dramatically. For example, the measured single-spike learning rule between hippocampal CA3 and CA1 pyramidal neurons does not predict the existence of long-term potentiation one of the best-known forms of synaptic plasticity. Layers of complexity have been added to the basic STDP model to repair predictive failures, but they have been outstripped by experimental data. We propose an alternate first law: neural activity triggers changes in key biochemical intermediates, which act as a more direct trigger of plasticity mechanisms. One particularly successful model uses intracellular calcium as the intermediate and can account for many observed properties of bidirectional plasticity. In this formulation, STDP is not itself the basis for explaining other forms of plasticity, but is instead a consequence of changes in the biochemical intermediate, calcium. Eventually a mechanism-based framework for learning rules should include other messengers, discrete change at individual synapses, spread of plasticity among neighboring synapses, and priming of hidden processes that change a synapse's susceptibility to future change. Mechanism-based models provide a rich framework for the computational representation of synaptic plasticity

Electrophysiological evidence for memory schemas in the rat hippocampus

According to Piaget and Bartlett, learning involves both assimilation of new memories into networks of preexisting knowledge and alteration of existing networks to accommodate new information into existing schemas. Recent evidence suggests that the hippocampus integrates related memories into schemas that link representations of separately acquired experiences. In this thesis, I first review models for how memories of individual experiences become consolidated into the structure of world knowledge. Disruption of consolidated memories can occur during related learning, which suggests that consolidation of new information is the reconsolidation of related memories. The accepted role of the hippocampus during memory consolidation and reconsolidation suggests that it is also involved in modifying appropriate schemas during learning. To study schema development, I trained rats to retrieve rewards at different loci on a maze while recording hippocampal calls. About a quarter of cells were active at multiple goal sites, though the ensemble as a whole distinguished goal loci from one another. When new goals were introduced, cells that had been active at old goal locations began firing at the new locations. This initial generalization decreased in the days after learning. Learning also caused changes in firing patterns at well-learned goal locations. These results suggest that learning was supported by modification of an active schema of spatially related reward loci. In another experiment, I extended these findings to explore a schema of object and place associations. Ensemble activity was influenced by a hierarchy of task dimensions which included: experimental context, rat's spatial location, the reward potential and the identity of sampled objects. As rats learned about new objects, the cells that had previously fired for particular object-place conjunctions generalized their firing patterns to new conjunctions that similarly predicted reward. In both experiments, I observed highly structured representations for a set of related experiences. This organization of hippocampal activity counters key assumptions in standard models of hippocampal function that predict relative independence between memory traces. Instead, these findings reveal neural mechanisms for how the hippocampus develops a relational organization of memories that could support novel, inferential judgments between indirectly related events

Microcircuit remodeling processes underlying learning in the adult

One of the most intriguing discoveries in neuroscience of the past decades has been showing that experience is able to induce structural modifications in cortical microcircuit that might underlie the formation of memories upon learning (for a review, see Caroni, Donato and Muller 2012). Hence, learning induces phases of synapse formation and elimination that are strictly regulated by a variety of mechanisms, which impact on cortical microcircuits affecting both excitatory and inhibitory neurons. Nevertheless, the extent to which specific configurations might be implemented to support specific phases of learning, as well as the impact of experience-induced structural modifications on further learning, is still largely unknown. Here, I explore how the remodeling of identified microcircuits in the mouse hippocampus and neocortex supports learning in the adult. In the first part, I identifiy a microcircuit module engaging VIP and Parvalbumin (PV) positive interneurons to regulate the state of the PV+ network upon experience. This defines states of enhanced or reduced structural plasticity and learning based on the distribution of PV intensity in the network. In the second part, I demonstrate how specific hippocampal subdivisions are exploited to learn subtasks of trial-and-errors forms of learning via the deployment of increasingly precise searching strategies, and sequential recruitment of ventral, intermediate, and dorsal hippocampus. In the third part, I highlight the existence of genetically matched subpopulations of principal cells in the hippocampus, which achieve selective connectivity across hippocampal subdivisions via matched windows of neurogenesis and synaptogenesis during development. In the fourth part, I investigate the maturation of microcircuits mediating feedforward inhibition in the hippocampus, and highlight windows during development for the establishment of the proper baseline configuration in the adult. Moreover, I identify a critical window for cognitive enhancement during hippocampal development. In the fifth part, I study how ageing affects the PV network in hippocampal CA3, providing evidence for which age related neuronal loss correlates to reduced incidental learning performances in old mice. Therefore, by manipulating the PV network early during life, I provide strategies to modulate cognitive decline

Slow Inhibition and Inhibitory Recruitment in the Hippocampal Dentate Gyrus

L’hippocampe joue un rôle central dans la navigation spatiale, la mémoire et l’organisation spatio-temporelle des souvenirs. Ces fonctions sont maintenues par la capacité du gyrus denté (GD) de séparation des patrons d'activité neuronales. Le GD est situé à l’entrée de la formation hippocampique où il reconnaît la présence de nouveaux motifs parmi la densité de signaux afférant arrivant par la voie entorhinale (voie perforante). Le codage parcimonieux est la marque distinctive du GD. Ce type de codage est le résultat de la faible excitabilité intrinsèque des cellules granulaires (CGs) en combinaison avec une inhibition locale prédominante. En particulier, l’inhibition de type « feedforward » ou circuit inhibiteur antérograde, est engagée par la voie perforante en même temps que les CGs. Ainsi les interneurones du circuit antérograde fournissent des signaux GABAergique aux CGs de manière presque simultanée qu’elles reçoivent les signaux glutamatergiques. Cette thèse est centrée sur l’étude des interactions entre ces signaux excitateurs de la voie entorhinale et les signaux inhibiteurs provenant des interneurones résidant dans le GD et ceci dans le contexte du codage parcimonieux et le patron de décharge en rafale caractéristique des cellules granulaires. Nous avons adressé les relations entre les projections entorhinales et le réseau inhibitoire antérograde du GD en faisant des enregistrements électrophysiologiques des CG pendant que la voie perforante est stimulée de manière électrique ou optogénétique. Nous avons découvert un nouvel mécanisme d’inhibition qui apparait à délais dans les CGs suite à une stimulation dans les fréquences gamma. Ce mécanisme induit une hyperpolarisation de longue durée (HLD) et d’une amplitude prononce. Cette longue hyperpolarisation est particulièrement prolongée et dépasse la durée d’autres types d’inhibition transitoire lente décrits chez les CGs. L’induction de HLD crée une fenêtre temporaire de faible excitabilité suite à laquelle le patron de décharge des CGs et l’intégration d’autres signaux excitateurs sont altérés de manière transitoire. Nous avons donc conclu que l’activité inhibitrice antérograde joue un rôle central dans les processus de codage dans le GD. Cependant, alors qu’il existe une multitude d’études décrivant les interneurones qui font partie de ce circuit inhibiteur, la question de comment ces cellules sont recrutées par la voie entorhinale reste quelque peu explorée. Pour apprendre plus à ce sujet, nous avons enregistré des interneurones résidant iii dans la couche moléculaire du GD tout en stimulant la voie perforante de manière optogénétique. Cette méthode de stimulation nous a permis d’induire la libération de glutamate endogène des terminales entorhinales et ainsi d’observer le recrutement purement synaptique d’interneurones. De manière surprenante, les résultats de cette expérience démontrent un faible taux d’activation des interneurones, accompagné d’un tout aussi faible nombre total de potentiels d’action émis en réponse à la stimulation même à haute fréquence. Ce constat semble contre-intuitif étant donné qu’en générale on assume qu’une forte activité inhibitrice est requise pour le maintien du codage parcimonieux. Tout de même, l’analyse des patrons de décharge des interneurones qui ont été activés a fait ressortir la prééminence de trois grands types: décharge précoce, retardée ou régulière par rapport le début des pulses lumineux. Les résultats obtenus durant cette thèse mettent la lumière sur l’important conséquences fonctionnelles des interactions synaptique et polysynaptique de nature transitoire dans les réseaux neuronaux. Nous aimerions aussi souligner l’effet prononcé de l’inhibition à court terme du type prolongée sur l’excitabilité des neurones et leurs capacités d’émettre des potentiels d’action. De plus que cet effet est encore plus prononcé dans le cas de HLD dont la durée dépasse souvent la seconde et altère l’intégration d’autres signaux arrivants simultanément. Donc on croit que les effets de HLD se traduisent au niveau du réseaux neuronal du GD comme une composante cruciale pour le codage parcimonieux. En effet, ce type de codage semble être la marque distinctive de cette région étant donné que nous avons aussi observé un faible niveau d’activation chez les interneurones. Cependant, le manque d’activité accrue du réseau inhibiteur antérograde peut être compensé par le maintien d’un gradient GABAergique constant à travers le GD via l’alternance des trois modes de décharges des interneurones. En conclusion, il semble que le codage parcimonieux dans le GD peut être préservé même en absence d’activité soutenue du réseau inhibiteur antérograde et ceci grâce à des mécanismes alternatives d’inhibition prolongée à court terme.The hippocampus is implicated in spatial navigation, the generation and recall of memories, as well as their spatio-temporal organization. These functions are supported by the processes of pattern separation that occurs in the dentate gyrus (DG). Situated at the entry of the hippocampal formation, the DG is well placed to detect and sort novelty patterns amongst the high-density excitatory signals that arrive via the entorhinal cortex (EC). A hallmark of the DG is sparse encoding that is enabled by a combination of low intrinsic excitability of the principal cells and local inhibition. Feedforward inhibition (FFI) is recruited directly by the EC and simultaneously with the granule cells (GCs). Therefore, FFI provides fast GABA release and shapes input integration at the millisecond time scale. This thesis aimed to investigate the interplay of entorhinal excitatory signals with GCs and interneurons, from the FFI in the DG, in the framework of sparse encoding and GC’s characteristic burst firing. We addressed the long-range excitation – local inhibitory network interactions using electrophysiological recordings of GCs – while applying an electrical or optogenetic stimulation of the perforant path (PP) in the DG. We discovered and described a novel delayed-onset inhibitory post synaptic potential (IPSP) in GCs, following PP stimulation in the gamma frequency range. Most importantly, the IPSP was characterized by a large amplitude and prolonged decay, outlasting previously described slow inhibitory events in GCs. The long-lasting hyperpolarization (LLH) caused by the slow IPSPs generates a low excitability time window, alters the GCs firing pattern, and interferes with other stimuli that arrive simultaneously. FFI is therefore a key player in the computational processes that occurs in the DG. However, while many studies have been dedicated to the description of the various types of the interneurons from the FFI, the question of how these cells are synaptically recruited by the EC remains not entirely elucidated. We tackled this problem by recording from interneurons in the DG molecular layer during PP-specific optogenetic stimulation. Light-driven activation of the EC terminals enabled a purely synaptic recruitment of interneurons via endogenous glutamate release. We found that this method of stimulation recruits only a subset of interneurons. In addition, the total number of action potentials (AP) was surprisingly low even at high frequency stimulation. This result is counterintuitive, as strong and persistent inhibitory signals are assumed to restrict GC v activation and maintain sparseness. However, amongst the early firing interneurons, late and regular spiking patterns were clearly distinguishable. Interestingly, some interneurons expressed LLH similar to the GCs, arguing that it could be a commonly used mechanism for regulation of excitability across the hippocampal network. In summary, we show that slow inhibition can result in a prolonged hyperpolarization that significantly alters concurrent input’s integration. We believe that these interactions contribute to important computational processes such as sparse encoding. Interestingly, sparseness seems to be the hallmark of the DG, as we observed a rather low activation of the interneuron network as well. However, the alternating firing of ML-INs could compensate the lack of persistent activity by the continuous GABA release across the DG. Taken together these results offer an insight into a mechanism of feedforward inhibition serving as a sparse neural code generator in the DG