Pre- and postsynaptic N-methyl-D-aspartate receptors are required for sequential printing of fear memory engrams

Impaired synaptic plasticity in behaving mice by inactivation of presenilin and accumulation of the neurexin gamma-secretase proteolytic substrate

Mutations in presenilin (PSEN1/2) genes are the main cause of familial Alzheimer's disease (fAD). Presenilin (PS) form the active component of the gamma-secretase complex, a protease that cleaves the C-terminal fragment (CTF) of multiple membrane proteins. The generation of mice lacking Psen1/2 genes in adult forebrain and of knockin mice expressing fAD-linked PSEN1 mutations favored a loss of function mechanism for PS/gamma-secretase in AD. In vitro, inactivation of PS impairs short- and long-term plasticity, but if PS regulates synaptic plasticity in vivo is not known, nor is it known the contribution of specific gamma-secretase substrates. In this study, we performed electrophysiological recordings at medial prefrontal cortex-basolateral (mPFC-BLA) synapse of behaving mice during fear conditioning, a type of associative memory. In controls, fear-conditioning decreases paired-pulse facilitation of the mPFC-BLA synapse, likely reflecting a memory-dependent increase in release probability. In contrast, PScKOtam mice lacking Psen1/2 genes in forebrain neurons in a tamoxifen-regulated manner show decreased paired-pulse facilitation at mPFC-BLA synapse along with impaired memory. Neurexins (Nrxns) are presynaptic membrane proteins processed by PS/gamma-secretase. Importantly, paired-pulse facilitation is further decreased in PScKOtam;NrxnCTF mice expressing increased NrxnCTF levels in PS-deficient neurons. Moreover, high-frequency stimulation induces long-term potentiation (LTP) at mPFC-BLA synapse of control mice, but LTP is impaired in PScKOtam mice and fully inhibited in PScKOtam;NrxnCTF mice. These findings suggest that PS enables learning-dependent adaptations in short and long-term synaptic plasticity by, at least in part, preventing the accumulation of NrxnCTF, pointing at NrxnCTF as a relevant factor downstream of PS dysfunction in AD.

Effects of anxiety induced by conditioned fear on the expression of NMDA receptors and synaptic plasticity in the rat BLA

NMDA receptors (NMDAR) are vital in CNS activities such as anxiety, memory, and cognition, and the neurobiological mechanisms behind anxiety disorders are exceedingly complicated. The "glutamic acid theory" posits that glutamate excitotoxicity is a key pathophysiological mechanism in anxiety disorders. However, the exact mechanism by which conditioned fear contributes to anxiety disorders remains unknown.Based on the conditioned fear-induced anxiety disorder model, this work aims to investigate changes in NMDAR and related proteins throughout the acquisition and expression of fear memory, as well as the impact on synaptic structural and functional plasticity. Injecting the NMDA receptor endogenous agonist D-Serine (50 μg/μL) and the noncompetitive antagonist MK-801 (1 μg/μL) into the lateral ventricle of the conditioned fear model rats, as well as conducting behavioral observations, show that NMDAR are closely involved in the development of conditioned fear-induced anxiety. Model rats showed significant changes in glutamate (Glu) and γ-aminobutyric acid (GABA) levels in the amygdala (BLA), as well as expression of NMDAR and downstream BDNF/TrkB signaling pathway components. At the same time, model rats exhibited synaptic and neuronal injury, aberrant long-term potentiation (LTP), and decreased expression of essential synaptic proteins SYP and PSD-95. In conclusion, our study demonstrates that NMDAR and synaptic plasticity play a critical role in the development of conditioned fear-induced anxiety, serving as an important reference for understanding the neurobiological underpinnings of anxiety disorders and providing insights into their treatment and new possible targets.

Estrogen Receptor Beta Agonist Influences Presynaptic NMDA Receptor Distribution in the Paraventricular Hypothalamic Nucleus Following Hypertension in a Mouse Model of Perimenopause

Women become susceptible to hypertension as they transition to menopause (i.e., perimenopause); however, the underlying mechanisms are unclear. Animal studies using an accelerated ovarian failure (AOF) model of peri-menopause (peri-AOF) demonstrate that peri-AOF hypertension is associated with increased postsynaptic NMDA receptor plasticity in the paraventricular hypothalamic nucleus (PVN), a brain area critical for blood pressure regulation. However, recent evidence indicates that presynaptic NMDA receptors also play a role in neural plasticity. Here, using immuno-electron microscopy, we examine the influence of peri-AOF hypertension on the subcellular distribution of the essential NMDA GluN1 receptor subunit in PVN axon terminals in peri-AOF and in male mice. Hypertension was produced by 14-day slow-pressor angiotensin II (AngII) infusion. The involvement of estrogen signaling was investigated by co-administering an estrogen receptor beta (ERß) agonist. Although AngII induced hypertension in both peri-AOF and male mice, peri-AOF females showed higher cytoplasmic GluN1 levels. In peri-AOF females, activation of ERß blocked hypertension and increased plasmalemmal GluN1 in axon terminals. In contrast, stimulation of ERß did not inhibit hypertension or influence presynaptic GluN1 localization in males. These results indicate that sex-dependent recruitment of presynaptic NMDA receptors in the PVN is influenced by ERß signaling in mice during early ovarian failure.

Involvement of prelimbic cortex neurons and related circuits in the acquisition of a cooperative learning by pairs of rats

Social behaviors such as cooperation are crucial for mammals. A deeper knowledge of the neuronal mechanisms underlying cooperation can be beneficial for people suffering from pathologies with impaired social behavior. Our aim was to study the brain activity when two animals synchronize their behavior to obtain a mutual reinforcement. In a previous work, we showed that the activity of the prelimbic cortex (PrL) was enhanced during cooperation in rats, especially in the ones leading most cooperative trials (leader rats). In this study, we investigated the specific cells in the PrL contributing to cooperative behaviors. To this end, we collected rats' brains at key moments of the learning process to analyze the levels of c-FOS expression in the main cellular groups of the PrL. Leader rats showed increased c-FOS activity in cells expressing D1 receptors during cooperation. Besides, we analyzed the levels of anxiety, dominance, and locomotor behavior, finding that leader rats are in general less anxious and less dominant than followers. We also recorded local field potentials (LFPs) from the PrL, the nucleus accumbens septi (NAc), and the basolateral amygdala (BLA). A spectral analysis showed that delta activity in PrL and NAc increased when rats cooperated, while BLA activity in delta and theta bands decreased considerably during cooperation. The PrL and NAc also increased their connectivity in the high theta band during cooperation. Thus, the present work identifies the specific PrL cell types engaged in this behavior, as well as the way this information is propagated to selected downstream brain regions (BLA, NAc).

Supplementary Information

The online version contains supplementary material available at 10.1007/s11571-024-10107-y.

Dentate gyrus is needed for memory retrieval

The hippocampus is crucial for acquiring and retrieving episodic and contextual memories. In previous studies, the inactivation of dentate gyrus (DG) neurons by chemogenetic- and optogenetic-mediated hyperpolarization led to opposing conclusions about DG's role in memory retrieval. One study used Designer Receptors Exclusively Activated by Designer Drugs (DREADD)-mediated clozapine N-oxide (CNO)-induced hyperpolarization and reported that the previously formed memory was erased, thus concluding that denate gyrus is needed for memory maintenance. The other study used optogenetic with halorhodopsin induced hyperpolarization and reported and dentate gyrus is needed for memory retrieval. We hypothesized that this apparent discrepancy could be due to the length of hyperpolarization in previous studies; minutes by optogenetics and several hours by DREADD/CNO. Since hyperpolarization interferes with anterograde and retrograde neuronal signaling, it is possible that the memory engram in the dentate gyrus and the entorhinal to hippocampus trisynaptic circuit was erased by long-term, but not with short-term hyperpolarization. We developed and applied an advanced chemogenetic technology to selectively silence synaptic output by blocking neurotransmitter release without hyperpolarizing DG neurons to explore this apparent discrepancy. We performed in vivo electrophysiology during trace eyeblink in a rabbit model of associative learning. Our work shows that the DG output is required for memory retrieval. Based on previous and recent findings, we propose that the actively functional anterograde and retrograde neuronal signaling is necessary to preserve synaptic memory engrams along the entorhinal cortex to the hippocampal trisynaptic circuit.

Functional states of prelimbic and related circuits during the acquisition of a GO/noGO task in rats

GO/noGO tasks enable assessing decision-making processes and the ability to suppress a specific action according to the context. Here, rats had to discriminate between 2 visual stimuli (GO or noGO) shown on an iPad screen. The execution (for GO) or nonexecution (for noGO) of the selected action (to touch or not the visual display) were reinforced with food. The main goal was to record and to analyze local field potentials collected from cortical and subcortical structures when the visual stimuli were shown on the touch screen and during the subsequent activities. Rats were implanted with recording electrodes in the prelimbic cortex, primary motor cortex, nucleus accumbens septi, basolateral amygdala, dorsolateral and dorsomedial striatum, hippocampal CA1, and mediodorsal thalamic nucleus. Spectral analyses of the collected data demonstrate that the prelimbic cortex was selectively involved in the cognitive and motivational processing of the learning task but not in the execution of reward-directed behaviors. In addition, the other recorded structures presented specific tendencies to be involved in these 2 types of brain activity in response to the presentation of GO or noGO stimuli. Spectral analyses, spectrograms, and coherence between the recorded brain areas indicate their specific involvement in GO vs. noGO tasks.