CA1 Neurons Research Articles

Neuronal PLPP/CIN exaggerates the immune response of hippocampal microglia to LPS challenge dependent on PAK1-NF-κB-COX-2 signaling pathway

Recently, we have reported that pyridoxal-5′-phosphate phosphatase/chronophin (PLPP/CIN) selectively dephosphorylates neurofibromin 2 (NF2, also known as merlin) at serine (S) 10 site. Since NF2 inhibits p21-activated kinase 1 (PAK1)-mediated nuclear factor-κB (NF-κB) activation, in the present study, we investigated the role of PLPP/CIN-mediated NF2 S10 dephosphorylation in lipopolysaccharide (LPS)-induced neuroinflammation and explored its related signaling pathways in the mouse hippocampus. PLPP/CIN overexpression increased NF2 S10 dephosphorylation and PAK1 S204 autophosphorylation under physiological condition, which were reversed by PLPP/CIN deletion. Following LPS injection, PLPP/CIN overexpression exacerbated microglial activation, although microglial PLPP/CIN expression was undetectable. In addition, PLPP/CIN overexpression enhanced PAK1 and NF-κB phosphorylations, and upregulated cyclooxygenase-2 (COX-2) and prostaglandin E synthase 2 (PTGES2) expressions in CA1 neurons. PLPP/CIN overexpression also augmented microglial interleukin-1β induction. PLPP/CIN ablation and 1,1′-dithiodi-2-naphthtol (IPA-3, a PAK1 inhibitor) pretreatment ameliorated these LPS-induced neuroinflammatory responses. These findings indicate that PLPP/CIN-mediated NF2 S10 dephosphorylation may facilitate PAK1-NF-κB-COX-2-PTGES2 signaling pathway in CA1 neurons, which would subsequently exaggerate immune response of microglia following LPS treatment. Therefore, our findings suggest that this PLPP/CIN-mediated neuron-microglia interaction may play an important role in the pathogenesis of inflammation-related neurological diseases.

Dysregulation of neuropilin-2 expression in inhibitory neurons impairs hippocampal circuit development and enhances risk for autism-related behaviors and seizures.

Dysregulation of development, migration, and function of interneurons, collectively termed interneuronopathies, have been proposed as a shared mechanism for autism spectrum disorders (ASDs) and childhood epilepsy. Neuropilin-2 (Nrp2), a candidate ASD gene, is a critical regulator of interneuron migration from the median ganglionic eminence (MGE) to the pallium, including the hippocampus. While clinical studies have identified Nrp2 polymorphisms in patients with ASD, whether selective dysregulation of Nrp2-dependent interneuron migration contributes to pathogenesis of ASD and enhances the risk for seizures has not been evaluated. We tested the hypothesis that the lack of Nrp2 in MGE-derived interneuron precursors disrupts the excitation/inhibition balance in hippocampal circuits, thus predisposing the network to seizures and behavioral patterns associated with ASD. Embryonic deletion of Nrp2 during the developmental period for migration of MGE derived interneuron precursors (iCKO) significantly reduced parvalbumin, neuropeptide Y, and somatostatin positive neurons in the hippocampal CA1. Consequently, when compared to controls, the frequency of inhibitory synaptic currents in CA1 pyramidal cells was reduced while frequency of excitatory synaptic currents was increased in iCKO mice. Although passive and active membrane properties of CA1 pyramidal cells were unchanged, iCKO mice showed enhanced susceptibility to chemically evoked seizures. Moreover, iCKO mice exhibited selective behavioral deficits in both preference for social novelty and goal-directed learning, which are consistent with ASD-like phenotype. Together, our findings show that disruption of developmental Nrp2 regulation of interneuron circuit establishment, produces ASD-like behaviors and enhanced risk for epilepsy. These results support the developmental interneuronopathy hypothesis of ASD epilepsy comorbidity.

Early and late place cells during postnatal development of the hippocampus

A proportion of hippocampal CA1 neurons function as place cells from the onset of navigation, which are referred to as early place cells. It is not clear whether this subset of neurons is predisposed to become place cells during early stages, or if all neurons have this potential. Here, we longitudinally imaged the activity of CA1 neurons in developing male rats during navigation with both one-photon and two-photon microscopy. Our results suggested that a largely consistent population of cells functioned as early place cells, demonstrating higher spatial coding abilities across environments and a tendency to form more synchronous cell assemblies. Early place cells were present in both deep and superficial layers of CA1. Cells in the deep layer exhibited greater synchrony than those in the superficial layer during early ages. These results support the theory that an initial cognitive map is primarily shaped by a predetermined set of hippocampal cells.

Postsynaptic dopamine D3 receptors selectively modulate μ opioid receptor-expressing GABAergic inputs onto CA1 pyramidal cells in the rat ventral hippocampus.

Although the actions of dopamine throughout the brain are clearly linked to motivation and cognition, the specific role(s) of dopamine in the CA1 subfield of the ventral hippocampus (vH) is unresolved. Prior preclinical studies suggest that dopamine D3 receptors (D3R) expressed on CA1 pyramidal cells exhibit a unique capacity to modulate mechanisms of long-term synaptic plasticity, but less is known about how interneurononal inputs modulate these cells. We hypothesized that inputs from μ opioid receptor (MOR)-expressing inhibitory interneurons selectively modulate the activity of postsynaptic D3Rs expressed on CA1 principal cells to shape neurotransmission in the rat vH. We used the whole-cell voltage clamp technique to test this hypothesis by measuring evoked inhibitory postsynaptic currents (eIPSCs) from CA1 principal cells in vH slices or GABAA currents from acutely dissociated vH neurons. The eIPSC response recorded from CA1 neurons in vH slices was inhibited by either the MOR agonist DAMGO or the D3R agonist PD128907, but pretreatment with DAMGO occluded any further inhibition by PD128907. GABAA currents measured in acutely dissociated vH CA1 neurons were inhibited by D3R activation via PD128907, consistent with postsynaptic localization of D3 receptors. Kinetic alterations induced by the neuromodulatory agonists are consistent with selective targeting of postsynaptic D3Rs expressed on CA1 principal cells by MOR-expressing GABAergic inputs. Our findings suggest postsynaptic D3R-mediated modulation of MOR-expressing GABAergic inputs is a site at which dopaminergic and opioidergic activity may contribute to disinhibition of vH excitatory neurotransmission, and, thus, influence critical physiological processes such as synaptic plasticity and network oscillations.

Effects of Black Rice Anthocyanin Extract on Depression-Like Behavior in Chronic Unpredictable Mild Stress Model Mice

Objective: To investigate the effects of black rice anthocyanins extract (BSE) on depression-like behavior in mice with chronic unpredictable mild stress (CUMS). Methods: A total of 30 male Kunming mice were randomly divided into Control group, model group (CUMS) and black rice anthocyanin extract group (300 mg/kg). Except the blank group, all mice were treated with CUMS to induce depression. After 21 days of intragastric administration, the behavioral changes of the mice were analyzed by body weight, sucrose preference test, open field test, and water maze test. Enzyme-linked immunosorbent assay (ELISA) was used to detect the levels of corticotropin-releasing hormone (CRH), adrenocorticotropic hormone (ACTH) and corticosterone (CORT). Hematoxylin-eosin staining (HE) was used to observe the pathological changes of neurons in hippocampal CA1 and CA3 regions. Cell apoptosis in hippocampus was detected by terminal deoxynucleotidyl transferase-mediated dutP Nick end labeling (TUNEL) staining. Results: Compared with the model group, the brown-rice anthocyanin treatment group showed significantly increased sucrose preference, increased horizontal movement distance and vertical standing times in the open field test, decreased escape latency in the water maze test, increased residence time in the target quadrant and the number of crossing the platform, and alleviated the damage of hippocampal neurons. Plasma ACTH, CORT, and CRH levels were decreased, and apoptosis rates in the hippocampus were decreased. Conclusion: Black rice anthocyanins have a significant antidepressant effect possibly by regulating the function of HPA axis.

Regulator of G protein signalling 14 (RGS14) protein expression profile in the adult mouse brain.

Regulator of G protein signalling 14 (RGS14) is a multifunctional signalling protein that serves as a natural suppressor of synaptic plasticity in the mouse brain. Our previous studies showed that RGS14 is highly expressed in postsynaptic dendrites and spines of pyramidal neurons in hippocampal area CA2 of the developing mouse brain. However, our more recent work with monkey brain shows that RGS14 is found in multiple neuron populations throughout hippocampal area CA1 and CA2, caudate nucleus, putamen, globus pallidus, substantia nigra and amygdala. In the mouse brain, we also have observed RGS14 protein in discrete limbic regions linked to reward behaviour and addiction, including the central amygdala and the nucleus accumbens, but a comprehensive mapping of RGS14 protein expression in the adult mouse brain is lacking. Here, we report that RGS14 is more broadly expressed in mouse brain than previously known. Intense RGS14 staining is observed in specific neuron populations of the hippocampal formation, amygdala, septum, bed nucleus of stria terminalis and ventral striatum/nucleus accumbens. RGS14 is also observed in axon fibre tracts including the dorsal fornix, fimbria, stria terminalis and the ventrohippocampal commissure. Moderate RGS14 staining is observed in various other adjacent regions not previously reported. These findings show that RGS14 is expressed in brain regions that govern aspects of core cognitive functions such as sensory perception, emotion, memory, motivation and execution of actions and suggest that RGS14 may serve to suppress plasticity and filter inputs in these brain regions to set the overall tone on experience-to-action processes.

Hippocampal area CA2 activity supports social investigation following an acute social stress.

Neuronal activity in the hippocampus is critical for many types of memory acquisition and retrieval and influences an animal's response to stress. Moreover, the molecularly distinct principal neurons of hippocampal area CA2 are required for social recognition memory and aggression in mice. To interrogate the effects of stress on CA2-dependent behaviors, we chemogenetically manipulated neuronal activity in vivo during an acute, socially derived stressor and tested whether memory for the defeat was influenced. One day after an acute social defeat (aSD), defeated mice spent significantly less time investigating another mouse when compared to non-defeated control mice. We found that this avoidant phenotype persisted for up to one month following a single defeat encounter. When CA2 pyramidal neuron activity was inhibited with Gi-DREADD receptors during the defeat, subject mice exhibited a significantly higher amount of social avoidance one day later when compared to defeated littermates not expressing DREADDs. Moreover, CA2 inhibition during defeat caused a reduction in submissive defense behaviors in response to aggression. In vitro electrophysiology and tracing experiments revealed a circuit wherein CA2 neurons connect to caudal CA1 projection neurons that, in turn, project to corticolimbic regions including the anterior cingulate cortex. Finally, socially avoidant, defeated mice exhibited significant reductions in cFos expression in caudal hippocampal and limbic brain areas during a social investigation task 24 h after aSD. Taken together, these results indicate that CA2 neuronal activity is required to support behavioral resilience following an acute social stressor and that submissive defensive behavior during the defeat (vs. fleeing) is a predictor of future resilience to social stress. Furthermore, CA2 preferentially targets a population of caudal CA1 projection neurons that contact cortical brain regions where activity is modulated by an acute social stressor.

Therapeutic effects of pentoxifylline in propionic acid-induced autism symptoms in rat models: A behavioral, biochemical, and histopathological study.

The role of propionic acid (PPA) in eliciting behaviors analogous to autism in rat models is a documented phenomenon. This study examines the therapeutic implications of pentoxifylline-an agent traditionally used for peripheral vascular diseases-on these autism-like behaviors by modulating brain proteins and reducing pro-inflammatory cytokines like tumor necrosis factor-α (TNF-α) in a rat model. This research involved 30 male Wistar albino rats, which were divided into three distinct groups: a baseline control set, a PPA-treated cluster receiving a 250 mg/kg/day dose of PPA via intraperitoneal injection for a span of five days followed by saline orally, and a PPA group administered an oral dose of pentoxifylline at 300 mg/kg/day over 15 days. Subsequent to the treatment phase, euthanasia was carried out for the extraction of brain and blood samples, which were then analyzed for histopathological and biochemical markers. The pentoxifylline-treated subjects demonstrated a significant mitigation in the manifestation of autistic-like behaviors, as assessed through a triad of social interaction tests. A noteworthy decline in TNF-α levels was observed, alongside a significant rise in the concentration of adenosine triphosphate and nerve growth factor in brain tissue (p < 0.05). Histopathological analysis underscored a reduction in oxidative stress and a significant preservation of neuronal cell types, specifically pyramidal neurons in the hippocampal CA1 and CA3 regions and Purkinje cells in the cerebellum (p < 0.001). Pentoxifylline treatment has been found to effectively reduce the behavioral symptoms associated with autism, as well as biochemical and histopathological disruptions induced by PPA in rat models, highlighting its potential as a neurotherapeutic agent.

Glucocorticoids Selectively Inhibit Hippocampal CA1 Pyramidal Neurons Activity Through HCN Channels.

Glucocorticoids are known to influence hippocampal function, but their rapid non-genomic effects on specific neurons in the hippocampal trisynaptic circuit remain underexplored. This study investigated the immediate effects of glucocorticoids on CA1 and CA3 pyramidal neurons, and dentate gyrus (DG) granule neurons in rats using the patch-clamp technique. We found that a 5 min extracellular application of corticosterone significantly reduced action potential firing frequency in CA1 pyramidal neurons, while no effects were observed in CA3 or DG neurons. The corticosterone-induced inhibition in CA1 was blocked by the glucocorticoid receptor antagonist CORT125281, but remained unaffected by the mineralocorticoid receptor antagonist spironolactone. Notably, membrane-impermeable bovine serum albumin-conjugated dexamethasone mimicked corticosterone's effects on CA1 neurons, which exhibited prominent hyperpolarization-activated cyclic nucleotide-gated (HCN) channel currents. Pyramidal neurons in CA3 and granular neurons in the DG showed little HCN channel currents. Corticosterone enhanced HCN channel activity in CA1 neurons via glucocorticoid receptors, and the HCN channel inhibitor ZD7288 abolished corticosterone's suppressive effects on action potentials. These findings suggest that glucocorticoids selectively inhibit CA1 pyramidal neuron activity through HCN channels, providing new insight into the mechanisms of glucocorticoid action in hippocampal circuits.

PKA regulation of neuronal function requires the dissociation of catalytic subunits from regulatory subunits

Protein kinase A (PKA) plays essential roles in diverse cellular functions. However, the spatiotemporal dynamics of endogenous PKA upon activation remain debated. The classical model predicts that PKA catalytic subunits dissociate from regulatory subunits in the presence of cAMP, whereas a second model proposes that catalytic subunits remain associated with regulatory subunits following physiological activation. Here, we report that different PKA subtypes, as defined by the regulatory subunit, exhibit distinct subcellular localization at rest in CA1 neurons of cultured hippocampal slices. Nevertheless, when all tested PKA subtypes are activated by norepinephrine, presumably via the β-adrenergic receptor, catalytic subunits translocate to dendritic spines but regulatory subunits remain unmoved. These differential spatial dynamics between the subunits indicate that at least a significant fraction of PKA dissociates. Furthermore, PKA-dependent regulation of synaptic plasticity and transmission can be supported only by wildtype, dissociable PKA, but not by inseparable PKA. These results indicate that endogenous PKA regulatory and catalytic subunits dissociate to achieve PKA function in neurons.

PKA regulation of neuronal function requires the dissociation of catalytic subunits from regulatory subunits.

Protein kinase A (PKA) plays essential roles in diverse cellular functions. However, the spatiotemporal dynamics of endogenous PKA upon activation remain debated. The classical model predicts that PKA catalytic subunits dissociate from regulatory subunits in the presence of cAMP, whereas a second model proposes that catalytic subunits remain associated with regulatory subunits following physiological activation. Here, we report that different PKA subtypes, as defined by the regulatory subunit, exhibit distinct subcellular localization at rest in CA1 neurons of cultured hippocampal slices. Nevertheless, when all tested PKA subtypes are activated by norepinephrine, presumably via the β-adrenergic receptor, catalytic subunits translocate to dendritic spines but regulatory subunits remain unmoved. These differential spatial dynamics between the subunits indicate that at least a significant fraction of PKA dissociates. Furthermore, PKA-dependent regulation of synaptic plasticity and transmission can be supported only by wildtype, dissociable PKA, but not by inseparable PKA. These results indicate that endogenous PKA regulatory and catalytic subunits dissociate to achieve PKA function in neurons.

Effects of synapse location, delay and background stochastic activity on synchronising hippocampal CA1 neurons

We study the synchronisation of neurons in a realistic model under the Hodgkin–Huxley dynamics. To focus on the role of the different locations of the excitatory synapses, we use two identical neurons where the set of input signals is grouped at two different distances from the soma. The system is intended to represent a CA1 hippocampal neuron in which the synapses arriving from the CA3 neurons of the trisynaptic pathway appear to be localised in the apical dendritic region and are, in principle, either proximal or distal to the soma. Synchronisation is studied using a specifically defined spiking correlation function as a function of various parameters such as the distance from the soma of one of the synaptic groups, the inhibition weight and the associated activation delay. We found that the neurons’ spiking activity depends nonmonotonically on the relative dendritic location of the synapses and their inhibition weight, while the synchronisation measure always decreases with inhibition, and strongly depends on its activation time delay. In our model, the synaptic random subthreshold background activity substantially reduces synchronisation in a monotonic way, while highlights the importance of a balanced E/I contribution for neuronal synchronisation.

High-Salt Diet Accelerates Neuron Loss and Anxiety in APP/PS1 Mice Through Serpina3n.

High salt (HS) consumption is an independent risk factor for neurodegenerative diseases such as dementia, stroke, and cerebral small vessel disease related to cognitive decline. Recently, Alzheimer's disease-like pathology changes have been reported as consequences of a HS diet in wild-type (wt) mice. However, it has not been revealed how HS diets accelerate the progress of Alzheimer's disease (AD) in APP/PS1 mice. Here, we fed APP/PS1 mice a HS diet or normal diet (ND) for six months; the effects of the HS/ND on wt mice were also observed. The results of our behavior test reveal that the HS diet exacerbates anxiety, β-amyloid overload, neuron loss, and synapse damage in the hippocampi of APP/PS1 mice; this was not observed in HS-treated wt mice. RNA sequencing shows that nearly all serpin family members were increased in the hippocampus of HS-treated APP/PS1 mice. Gene function analysis showed that a HS diet induces neurodegeneration, including axon dysfunction and neuro-ligand-based dysfunction, and regulates serine protein inhibitor activities. The mRNA and protein levels of Serpina3n were dramatically increased. Upregulated Serpina3n may be the key for β-amyloid aggregation and neuronal loss in the hippocampus of HS-treated APP/PS1 mice. Serpina3n inhibition attenuated the anxiety and increased the number of neurons in the hippocampal CA1(cornu ammonis) region of APP/PS1 mice. Our study provides novel insights into the mechanisms by which excessive HS diet deteriorates anxiety in AD mice. Therefore, decreasing daily dietary salt consumption constitutes a pivotal public health intervention for mitigating the progression of neuropathology, especially for old patients and those with neurodegenerative disease.

3D mapping of direct VTA-CA2 circuit with potential involvement in Parkinson's disease degeneration

Parkinson's disease dementia (PDD) is commonly developed in patients at the late stage of Parkinson's disease (PD) with unknown progression mechanisms. From the post-mortem tissues and animal models, the ventral tegmental area (VTA) and the CA2 regions are closely associated with dementia development in PDD. However, the structural connection between the two regions has not been fully traced. In this study, we applied tissue clearing and adeno-associated virus (AAV) tracing to map the neural circuits in a 3D manner. Hence, we have confirmed the direct connection between the regions with two dual AAV tracing systems and traced the VTA-CA2 circuit in 3D reconstruction. With the immunostaining, we have shown that the GABAergic neurons are the potential subtype of the postsynaptic CA2 neurons in the VTA-CA2 circuit. Under the 6-hydroxydopamine (6-OHDA), we have demonstrated the degeneration of the VTA-CA2 circuit from the observation of fragmented axonal projections. Collectively, we have first traced the direct connection of the whole VTA-CA2 circuit in an intact 3D manner and monitored the fragmentation of this target circuit in the 6-OHDA model. This VTA-CA2 circuit can be a target for future studies of the pathological spreading and degeneration mechanism from PD to PDD.

Increasing Adult Hippocampal Neurogenesis affects Neuronal Output Pattern from the Ventral Subiculum to the Hypothalamus

Adult Hippocampal Neurogenesis, or AHN, has been discovered to alleviate anxiety and depressive behavior, thus leading to the presumption that the mechanisms underlying it might be somewhat linked to the regulatory circuitry of anxiety and depression. The subiculum is a region of the Hippocampus connecting the CA1 neurons and the Entorhinal cortex. It is the main output region of the Hippocampus. A great portion of the subiculum neurons form neuronal projections to the lateral hypothalamus, which is known to play a crucial role in the regulation of anxiety via hormone secretion in both rodents and humans. Thus, we hypothesize that Adult Hippocampal Neurogenesis regulates anxiety via altering the neural output from the subiculum to the lateral hypothalamus. In this research proposal we aim to prove that increasing AHN causes a direct impact on neuronal activity in the main output region of the Hippocampus--the subiculum region, under the effect of anxiety. This study uses the Fos-TRAP2 model to induce tdTomato expression in neurons with high recent activity while the mice was under the effect of corticosterone-induced anxiety. We compare the amount of TRAPed neurons in the subiculum region of the brain during anxiety, in mice with and without weeks of voluntary exercise (running), which leads to an increased neurogenesis. This provides insight into the effects of AHN on the subiculum-hypothalamus pathway, thus the mechanisms underlying its effect of anxiety alleviation.

Prenatal ethanol exposure impairs hippocampal plasticity and cognition in adolescent mice

BackgroundPrenatal alcohol exposure (PAE) induces a wide range of neurodevelopmental disabilities that are grouped under the term ‘fetal alcohol spectrum disorders’ (FASD). The effects of PAE on brain development are dependent on complex neurochemical events, including modification of AMPA receptors (AMPARs). We have recently found that chronic ethanol (EtOH) exposure decreases AMPA-mediated neurotransmission and expression through the overexpression of the specific microRNA (miR)137 and 501-3p, which target GluA1 AMPA subunit, in the developing hippocampus in vitro. Here, we explored how PAE mice may alter AMPAergic synapses in the hippocampus, and its effects on behavior. MethodsTo model PAE, we exposed C57Bl/6 pregnant mice to 10 % EtOH during during the first 10 days of gestation (GD 0–10; equivalent to the first trimester of pregnancy in humans). AMPA subunits postsynaptic expression in the hippocampus, electrical properties of CA1 neurons, memory recognition, and locomotor functions were then analyzed in adolescent PAE-exposed offspring. ResultsPAE adolescent mice showed dysregulation of AMPAergic neurotransmission, and increased miR 501-3p expression, associated with a significant reduction of spontaneous AMPA currents and intrinsic somatic excitability. In addition, PAE reduced the phosphorylation of AMPAR-containing GluA1 subunit, despite an increase in its total levels. Of note, the total levels of GluA2 and GluA3 AMPA receptors were enhanced as well. Consistently, at behavioral level, PAE reduced object recognition without altering locomotor activity. ConclusionsOur study shows that PAE leads to dysfunctional formation of AMPAergic synapses that could be responsible for neurobehavioral impairments, contributing to the understanding of the pathogenesis of FASD.

The administration of a phentolamine infusion into the basolateral amygdala enhances long-term memory and diminishes anxiety-like behavior in stressed rats.

The basolateral amygdala (BLA) contains adrenergic receptors, which are known to be involved in stress, anxiety, and memory. The objective of this study was to explore whether inhibition of α-adrenergic receptors (by phentolamine, an α-adrenergic receptor antagonist) in the BLA can reduce foot-shock stress-induced anxiety-like behavior, memory deficits, and long-term potentiation (LTP) deficits within the CA1 region of the rat hippocampus. Forty male Wistar rats were assigned to the intact, control, stress (Str), Phent (phentolamine), and Phent + Str groups. Animals were subjected to six shocks on 4 consecutive days, and phentolamine was injected into BLA 20 min before the animals were placed in the foot-shock stress apparatus. Results from the elevated plus maze test (EPM) revealed a reduction in anxiety-like behaviors (by an increased number of entries into the open arm, percentage of time spent in the open arm, and rearing and freezing) among stressed animals upon receiving injections of phentolamine into the BLA. The open-field test results (increased rearing, grooming, and freezing behaviors) were consistent with the EPM test results. Phentolamine infusion into the BLA enhanced spatial memory, reducing errors in finding the target hole and decreasing latency time in the Barnes maze test for stress and nonstress conditions. Injecting phentolamine into the BLA on both sides effectively prevented LTP impairment in hippocampal CA1 neurons after being subjected to foot-shock stress. It has been suggested that phentolamine in the BLA can effectively improve anxiety-like behaviors and memory deficits induced by foot-shock stress.

Intervention effects of Naoxintong capsules on psychological and cardiac status in depressed rats after heart failure

Abstract Background Depression is a common clinical phenomenon in the patients with heart failure (HF). In traditional Chinese medicine (TCM), diseases in the brain and heart are thought to be correlated and interact. Naoxintong capsules (NXT) has been used for treating cardio-cerebrovascular diseases, while its therapeutic effect on depression after HF remains unclear. Objective The aim of the study is to evaluate the intervention effect of NXT on depression after HF. Methods Sprague-Dawley rats were assigned into the following 5 groups: sham, model, NXT (250, 1000 mg/kg), and valsartan (8 mg/kg). Coronary artery occlusion was performed to induce HF and subsequent depression in rats. The cardiac function was evaluated by echocardiography, hematoxylin-eosin staining, and Masson trichrome staining. The sucrose preference test and Morris water maze test were carried out to assess the depressive behaviors in rats. The ultrastructure of hippocampal CA1 neurons was observed and the levels of corticotropin-releasing hormone in the hypothalamus, brain-derived neurotrophic factor in the cortex, and adrenocorticotropic hormone (ACTH) in the plasma were determined by enzyme-linked immunosorbent assay. The levels of dopamine, 5-hydroxytryptamine, norepinephrine, and γ-aminobutyric acid in the hippocampus were measured by UPLC-QQQ-MS. Results NXT reduced myocardial injury and pathological changes in the cardiac tissue and increased the left ventricular ejection fraction, left ventricular fractional shortening, and cardiac output. NXT increased the sugar preference rate and number of crossings and shortened the escape latency. Furthermore, the NXT treatment restored the levels of corticotropin-releasing hormone, adrenocorticotropic hormone, brain-derived neurotrophic factor, dopamine, and γ-aminobutyric acid to the baseline values. Conclusions NXT not only demonstrates cardioprotective effect but also attenuates depression in the rats after HF. It may exert the antidepressant effect by inhibiting the hyperactivity of the hypothalamic-pituitary-adrenal axis and recovering the levels of neurotrophic factors and neurotransmitters.

Down regulation of the c-Fos/MAP kinase signaling pathway during learning memory processes coincides with low GnRH levels in aluminum chloride-induced Alzheimer's male rats.

Aluminum chloride (Al) is associated with Alzheimer's disease (AD) and reproductive disorders. But the relationship between gonadotropin-releasing hormone (GnRH) and c-Fos levels, the end product of MAP-kinase signaling, in AD is unknown, so we aimed to investigate this relationship. We exposed rats to Al dissolved in drinking water (10 and 50mg/kg) for two and four weeks. The control group received only drinking water. At the end, the blood sample was collected under deep anesthesia and the brain was dissected on ice, and the testicular tissue was fixed in formalin. Amyloid beta (βA) plaques in brain regions and the number of CA1 neurons were evaluated by Congo red staining and cresyl violet staining. Activation of neuronal nitric oxide synthase (nNOS) was studied using NADPH-diaphorase. The levels of c-Fos and testosterone receptors in the target area were examined immunohistochemically. Brain GnRH levels were determined by blotting, and serum levels of gonadotropins and steroids were measured by enzyme-linked immunosorbent assay (ELISA). All data were analyzed using analysis of variance (ANOVA) at α = 0.05 level. The accumulation of βA plaque was observed along with a decrease in the number of CA1 pyramidal neurons and a significant decrease in the levels of c-Fos and GnRH in the brains of rats receiving Al, which was aligned with a significant decrease in serum levels of testosterone and LH. This study, for the first time, showed a link between dementia and a concomitant decrease in brain GnRH and c-Fos levels.

Changes in early endosomes in rat hippocampal CA1 neurons after transient global cerebral ischaemia.

Transient global ischaemia in rodents causes selective loss of hippocampal CA1neurons, but the potential involvement of endocytic pathways has not been fully explored. The aim of this study was to investigate the changes in early endosomes in the CA1 subfield after ischaemia and reperfusion. A four-vessel occlusion (4-VO) model was established in Wistar rats to induce 13 minutes of global cerebral ischaemia. Neuronal death was detected by Fluoro-Jade B (FJ-B) staining at various intervals after reperfusion, and intracellular membrane changes in ischaemic neurons were revealed using DiOC6(3), a lipophilic fluorescent probe. Ras-related protein Rab5 (Rab5) immunostaining was performed to detect changes in early endosomes in ischaemic neurons. Western blot analysis was used to confirm the morphological observations on Rab5 in the CA1 hippocampal subfield. FJ-B staining confirmed progressive neuronal death in the CA1 subfield in ischaemic rats after reperfusion. DiOC6(3) staining revealed abnormally increased membranous components in ischaemic CA1 neurons. Specifically, early endosomes, as labelled by Rab5 immunostaining, significantly increased in number and size in CA1 neurons at 1.5 and 2 days post-reperfusion, followed by rupture at day 3 and a decrease in staining intensity at day 7 post-reperfusion. Western blot analysis confirmed a significant upregulation of Rab5 protein levels at day 2, which returned to near control levels by day 7. Our study revealed significant changes in the dynamics of early endosomes in CA1 neurons after ischaemia-reperfusion injury. The initial increase in the area fraction of early endosomes in CA1 neurons may reflect an upregulation of endocytic activity, whereas the fragmentation and reduction of early endosomes at the later stage may indicate a failure of adaptive mechanisms of ischaemic neurons against ischaemia-induced death. Understanding the temporal dynamics of early endosomes provides critical insights into the cellular mechanisms that govern fate of CA1 hippocampal neuronsl after ischaemia/reperfusion.