Search Results (262)

Background/Objectives: Yes-associated protein 1 (YAP1) is a transcriptional cofactor that coordinates the complex interplay between cell proliferation, survival, differentiation, metabolism, biomechanics, and tissue regeneration. Previous studies have shown that YAP1 activity is reduced during aging, and replacing YAP1 function has been shown to rejuvenate old cells by mitigating senescence and its associated inflammation. Methods: As YAP1 is now confirmed to exert a profound regenerative influence on multiple organs, we wanted to gain more insight into the molecular signature of YAP1 expression relevant to brain cells. Since proteomics is a very powerful tool for discoveries, we generated SH-SY5Y cells stably expressing GFP-YAP1 and screened 8000 human proteins using multiplex arrays that utilize biotin-label-based antibody arrays. Results: We found YAP1 expression in astrocytes, microglia, neuronal and neuroblastoma cell lines, as well as human neurons. Importantly, YAP1 protein levels were significantly reduced selectively in the nuclear fractions of the brains of patients with Alzheimer’s disease (AD) relative to normal control (NC) subjects. The screen resulted in the identification of 283 differentially expressed proteins. In line with YAP1’s known role in the regulation of actin and cytoskeleton, we found a 2.53-fold upregulated level of Rho guanine nucleotide exchange factor 1 (ARHGEF1), a guanine nucleotide exchange factor (GEF) for the RhoA GTPase, which is crucial for dendritic spine regulation. A 6.19-fold upregulated level of NECAP endocytosis-associated 2 (NECAP2), the highest known increase for any protein in this screen, plays an essential role in clathrin-mediated endocytosis. Most importantly, another upregulated protein was Neudesin Neurotrophic Factor (NENF) (3.07-fold increase), also known as Neudesin, which primarily acts as a neurotrophic factor, and it promotes neuronal survival, enhances cell proliferation, and neurogenesis in neural progenitor cells. Neural Precursor Cell Expressed, Developmentally Down-Regulated 9(NEDD9) levels were also upregulated by 2.46-fold, and it affects neuronal cell number and synaptic connections through its role in neurite formation. However, it should be noted that these proteomic results are preliminary in nature as they are derived from single-sample data. The upregulated levels of ARHGEF1 and NEDD9 were confirmed by immunoblots. We also found a drastic reduction in the levels of p16INK4a, a marker of senescence. Conclusions: Thus, the anti-senescence effect of YAP1 may be mediated through p16INK4a, which in turn may be crucial for YAP1’s regenerative functions through NENF and NEDD9. Full article

Mitochondrial dysfunction is a key contributor to cognitive impairment, directly affecting neuronal viability, synaptic function, and energy metabolism. In the central nervous system, where energy demand is particularly high, disturbances in mitochondrial dynamics, including impaired oxidative phosphorylation (OxPhos), increased reactive oxygen species (ROS) production, and reduced ATP availability, can compromise synaptic transmission and accelerate cognitive decline. These alterations are commonly observed in neurodegenerative diseases such as Alzheimer’s (AD) and Parkinson’s (PD), in which mitochondrial dysfunction is closely associated with oxidative stress and neuroinflammatory processes. This review aims to investigate the role of mitochondrial dysfunction in cognitive impairment and the effects of physical exercise as a non-pharmacological strategy to mitigate these alterations. Current evidence indicates that exercise promotes mitochondrial biogenesis through activation of the AMPK/PGC-1α pathway, enhances oxidative metabolism, and improves mitochondrial efficiency. Furthermore, exercise reduces oxidative stress and inflammation while stimulating the release of neurotrophic factors, such as brain-derived neurotrophic factor which support neurogenesis, synaptic plasticity, and neuronal survival. Overall, these findings reinforce the importance of mitochondrial integrity in maintaining cognitive function and highlight physical exercise as a promising strategy to counteract mitochondrial dysfunction and delay the progression of neurodegenerative diseases. Full article

Phospholipase A2 group VI (PLA2G6) regulates phospholipid remodeling and cellular homeostasis, and its mutations cause neurodegenerative disorders, including neurodegeneration with brain iron accumulation and PLA2G6-associated parkinsonism (PARK14). Although many cases present in adulthood, a substantial subset shows early onset, indicating that PLA2G6 dysfunction can affect neuronal systems during developmental stages. However, whether PLA2G6 directly regulates early neurogenesis remains undefined. Here, using zebrafish embryos, we investigated the role of Pla2g6 during neural development through loss- and gain-of-function approaches. pla2g6 is dynamically expressed during embryogenesis, with enrichment in the developing central nervous system during neurogenesis. CRISPR/Cas9-mediated Pla2g6 deficiency did not alter neural progenitor formation but significantly reduced neuronal precursors. Expression of the disease-associated PLA2G6 D331Y variant phenocopied this effect, confirming that the observed phenotype results from loss of Pla2g6 function. The reduction in neuronal precursors occurred without changes in proliferation but was accompanied by a marked increase in apoptosis, identifying neuronal precursor cell death as the primary mechanism. Under oxidative stress conditions, Pla2g6 overexpression reduced neuronal apoptosis, whereas Pla2g6 deficiency markedly enhanced reactive oxygen species -induced apoptosis. These findings establish Pla2g6 as a regulator of oxidative stress-associated apoptotic signaling during neurogenesis. Together, these results define Pla2g6 as a stage-specific determinant of neuronal precursor survival, linking lipid homeostasis and oxidative stress control to early neural development. This study establishes a developmental framework for PLA2G6-associated disorders and positions impaired neuronal precursor survival as a contributing mechanism underlying disease onset. Full article

This narrative review proposes the ‘Brain Health Triad’ as a novel integrative framework for neurorehabilitation and cognitive enhancement, built upon three interdependent biological pillars: neurostimulation, neurotrophy, and neuroprotection. We illustrate how the synergistic interplay between a ‘core triad’ composed of Hericium erinaceus, Bacopa monnieri, and L-Theanine targets these pillars with high specificity. Hericium erinaceus fosters neurotrophy by inducing Nerve Growth Factor (NGF) and Brain-derived neurotrophic factor (BDNF) synthesis through erinacines and hericenones; Bacopa monnieri complements this by enhancing neurostimulation and synaptic plasticity via bacosides; and L-Theanine regulates neurotransmitter balance and alpha-wave activity to stabilize the neural signaling environment. This core architecture is further reinforced by adjunctive nootropic clusters—including withanolides, ginkgolides, citicoline, cordycepin, macamides, and fulvic acid—which provide essential support for mitochondrial resilience and the mitigation of amyloid-β and tau toxicities. By synthesizing molecular evidence from the BDNF/TrkB/CREB signaling axis and the Nrf2/NF-κB homeostatic switch, we demonstrate that this multi-target strategy offers a more robust path to neuronal resilience than traditional single-target approaches. We conclude that this integrated model provides a solid framework for future clinical applications in the management of age-related cognitive decline and neurodegenerative diseases. Full article

Adult neurogenesis is a regulated form of brain plasticity shaped by interactions between hormonal systems and environmental context. Social experience has been identified as an important modulator of neuronal proliferation, differentiation, and survival across the lifespan, although effects vary across species, developmental stages, and experimental paradigms. This review synthesizes evidence indicating that diverse social behaviors—including isolation, social hierarchy, parenting, sexual interaction, social buffering, and social learning—engage neuroendocrine, neurochemical, and stress-related pathways that are associated with modulation of hippocampal and olfactory neurogenesis. Affiliative and reproductive contexts have been linked in multiple models to enhanced neurogenic indices via gonadal hormones, oxytocinergic and vasopressinergic signaling, and neurotrophic mechanisms, whereas chronic isolation or social defeat has frequently been associated with reduced neurogenic markers, particularly within stress-sensitive regions of the ventral dentate gyrus. Sex differences further shape these patterns, reflecting both biological regulation and uneven sampling across paradigms. Comparative findings in prairie voles, eusocial mole-rats, nonhuman primates, songbirds, and teleost fish indicate that social organization can be accompanied by either increased or constrained neurogenic activity, depending on ecological pressures and life-history strategies. Collectively, the available evidence suggests that adult neurogenesis represents a context-dependent plastic process embedded within vertebrate social systems, while underscoring the need for integrative and evidence-graded interpretations. Full article

This review examines the impact of physical exercises on fluid intelligence (FI) among elderly individuals with or without dementia. Fluid intelligence declines with age and worsens faster with dementia, and studies suggest that physical exercise, like aerobic and strength training, may improve fluid intelligence by enhancing neurogenesis, promoting cerebral blood flow, and increasing brain plasticity. A comprehensive search was carried out for studies from inception to 31 May 2024 across databases, including PubMed, Scopus, Web of Science, and PEDro, using keywords related to “physical activity”, “physical exercise”, “fluid intelligence”, and “dementia”. The inclusion criteria focused on randomized control trials (RCTs) involving elderly participants with or without dementia, where fluid intelligence was measured using validated tools. The PEDro scale was used for the quality assessment of included studies. Risk of bias assessment was done using the Cochrane risk of bias tool version 2. Out of 1982 screened studies (PubMed: 104; Web of Science: 1676; Scopus: 195; PEDro: six), five RCTs involving 676 participants were included. Interventions lasted 4 to 24 weeks and included aerobic training, flexibility training, combined strength, and cognitive training, amongst others. It is seen that low- and high-intensity aerobic exercises improved FI, whereas another study reported that combined physical and mental activity significantly enhanced executive function and processing speed. Overall, all included studies demonstrated improvements in FI following exercise interventions. Physical exercises may support fluid intelligence in older adults, but current evidence is limited to a small number of trials. More robust studies are required. Full article

Degenerative diseases are characterized by the gradual loss of cellular integrity, tissue function, and regenerative capacity. Cardiovascular diseases, neurodegenerative disorders, and musculoskeletal deterioration are considered major categories of degenerative diseases, and vitamin D deficiency has been linked with an increased risk of these conditions. Vitamin D has the potential to modulate neurogenerative process by influencing the progression of neuronal survival, neurogenesis, and synaptic plasticity through both genomic and non-genomic mechanisms mediated by vitamin D receptors, which are widely distributed across brain regions and cell types. Additionally, vitamin D regulates brain immunometabolism by modulating microglial and astrocytic inflammatory responses and oxidative stress. Vitamin D has long been recognized as essential for bone health. Beyond its classical role, vitamin D contributes to the maintenance of bone–muscle homeostasis, enhances mitochondrial biogenesis and ATP production while reducing oxidative stress, and facilitates bidirectional bone–muscle crosstalk through myokines and osteokines to coordinate bone remodeling and muscle regeneration. However, despite these mechanistic insights, the beneficial effects of vitamin D on these diseases—such as reduced risk or mitigation of progression—remains inconclusive. This review explores the relationships between vitamin D and cardiovascular, neurodegenerative, and musculoskeletal diseases, with a focus on the underlying immunological and metabolic mechanisms of actions. Full article

Ischemic stroke accounts for approximately 80–85% of all stroke cases and triggers a complex cascade of metabolic, immunological, and neurodegenerative processes. Among the key mediators involved, TNF-α occupies a central position due to its distinctly dual and phase-dependent actions. Importantly, the biological effects of TNF-α are not static but evolve dynamically over time following ischemic insult. During the acute phase of ischemia, a rapid increase in TNF-α levels, primarily originating from activated microglia, leads to the predominant activation of the TNFR1 receptor. This results in enhanced apoptosis and necroptosis, disruption of the blood–brain barrier, increased leukocyte recruitment, and the progression of secondary neuronal injury. In later phases, the role of TNF-α shifts, with signaling through TNFR2 becoming more prominent, thereby supporting reparative mechanisms, including neurogenesis, angiogenesis, and synaptic remodeling. The dual nature of TNF-α means that both its excessive activation and complete inhibition may produce detrimental effects. Notably, the therapeutic relevance of TNF-α critically depends on the timing of intervention relative to stroke onset. A comprehensive analysis of current evidence underscores the central, temporally and contextually dependent role of TNF-α in the pathophysiology of ischemic stroke. It also indicates that future therapeutic strategies should aim to selectively suppress the harmful TNFR1-mediated signaling while preserving or enhancing TNFR2-dependent neuroprotective pathways. Such time-sensitive and receptor-selective modulation holds promise for limiting acute ischemic injury and promoting endogenous repair processes, representing a compelling direction for the development of next-generation neuroprotective therapies. Full article

Hericium erinaceus (H. erinaceus), a medicinal mushroom, is a source of bioactive compounds with demonstrated neuroprotective potential. This activity is primarily attributed to two distinct classes of compounds: erinacines from the mycelium, which potently induce the synthesis of neurotrophins, protein growth factors essential for neuronal survival and health, and hericenones from the fruiting body, which subsequently appear to enhance or potentiate neurotrophin-activated signaling pathways. Preclinical evidence substantiates their ability to enhance neurotrophin levels, particularly Nerve Growth Factor (NGF) and Brain-Derived Neurotrophic Factor (BDNF), and activate their cognate Trk receptors. Activation of these pathways, including PI3K/AKT/mTOR and MAPK/ERK, converges on transcription factors such as CREB, promoting neuronal survival, neurite outgrowth, and synaptic plasticity. However, the precise molecular mechanisms linking these small molecules to the complex orchestration of neurotrophic gene expression remain incompletely defined. This review synthesizes current knowledge of the neurotrophic pharmacology of H. erinaceus bioactives and proposes a novel framework suggesting that non-coding RNAs (ncRNAs) play a key regulatory role. We hypothesize that hericenones and erinacines modulate key transcriptional hubs, such as CREB, Nrf2, and NF-κB, which in turn regulate the expression of specific ncRNAs (e.g., miR-132, miR-146a) known to control neurogenesis, synaptogenesis, oxidative stress, and neuroinflammation. This ncRNA-mediated mechanism may represent an un-explored axis that explains the pleiotropic neuroprotective effects of these compounds. We critically appraise the existing preclinical evidence, identify significant methodological limitations and translational gaps, and propose a structured research roadmap to test these ncRNA-centric hypotheses, aiming to accelerate the rational development of H. erinaceus-derived compounds for neurodegenerative diseases. Full article

Background: Moderate physical activity (PA) exerts powerful systemic and neuroprotective effects, reducing chronic disease risk and enhancing cognitive and psychological well-being. PA promotes brain plasticity by upregulating neurotrophic factors and stimulating neurogenesis. Given the established role of Pituitary Adenylate Cyclase-Activating Polypeptide (PACAP) in neuronal survival, differentiation, and anti-apoptotic signaling, we aimed to investigate whether moderate PA modulates the endogenous expression of PACAP and its specific receptor PAC1R in the DG and cerebellar cortex. Methods: To this end, twenty-four rats were distributed into sedentary or exercise groups. Immunohistochemical and Western blot analyses were performed to assess PACAP and PAC1R expression. Co-expression with doublecortin (DCX), a marker of immature neurons, was evaluated to explore the direct relationship between PACAP signaling and neurogenesis. Results: Our results showed that moderate PA induced a significant up-regulation of PACAP and PAC1R in both the DG and cerebellar cortex compared to sedentary controls. Moreover, high co-expression of PACAP and DCX was detected in these regions, suggesting an involvement of PACAP in exercise-induced neurogenic processes. Conclusions: These findings demonstrate that moderate physical activity is associated with enhanced PACAP/PAC1R signaling and DCX expression in neurogenic regions, warranting further investigation into its specific contribution to exercise-induced brain plasticity. Full article

Neurodegeneration—driven by oxidative stress, chronic inflammation, and protein aggregation—underlies disorders such as Alzheimer’s disease, Parkinson’s disease, Huntington’s disease, and stroke. Current pharmacological treatments are largely symptomatic and do not restore lost neural circuitry, motivating regenerative approaches. Mesenchymal stem cells (MSCs) provide neurotrophic and immunomodulatory benefits and can support synaptic repair, yet robust conversion into mature, electrophysiologically functional neurons remain challenging and often depends on complex inducer cocktails with translational limitations. Crocin, a saffron-derived carotenoid, is reported to enhance neurogenesis and neuroprotection in preclinical models through pathways including Wnt/β-catenin, Notch1, CREB/BDNF, and modulation of GSK-3β, while reducing apoptosis and inflammatory signaling. Here, we synthesize evidence supporting crocin’s neuroprotective and proneurogenic activity and propose a testable hypothesis that crocin-based or crocin-modified formulations could be evaluated as adjuncts to guide MSC neuronal lineage commitment. Importantly, direct evidence that crocin alone can drive MSC trans-differentiation into fully functional neurons is currently insufficient; future work should define functional benchmarks (electrophysiology, synaptogenesis, and phenotypic stability) and rigorously validate safety, dosing, and delivery strategies for neuroregenerative translation. Full article

Adult hippocampal neurogenesis (AHN) is a dynamic process that sustains neural plasticity and contributes to cognition, emotion, and stress resilience. While its functional significance in humans remains debated, growing evidence suggests that AHN plays an important role in health and disease. In this review, we summarize intrinsic and extrinsic factors that modulate AHN, with particular emphasis on hormones, behavior, diet, and their impact along the hippocampal dorsoventral axis, where baseline neurogenesis is higher dorsally, but ventral neurogenesis exhibits greater plasticity and sensitivity to modulatory systems. We highlight how cognitive stimulation, physical activity, and rewarding experiences preferentially enhance dorsal hippocampal neurogenesis, whereas chronic stress and glucocorticoids mainly impair neurogenesis in the ventral hippocampus. Nutritional influences such as caloric restriction, high-fat diets, vitamins, and polyphenols are also considered, with evidence for region-specific effects. We further examine the relevance of AHN alterations in neuropsychiatric diseases, such as major depressive disorder, schizophrenia, Alzheimer’s disease, and addiction, highlighting both common mechanisms and disorder-specific vulnerabilities. Collectively, current findings suggest that AHN serves as a converging pathway connecting lifestyle, neuroendocrine regulation, and psychiatric or neurodegenerative disease. Recognizing the dorsoventral specialization of AHN could refine mechanistic models of brain function and inform the development of targeted and distinct therapeutic strategies for cognitive and affective diseases. Full article

Major depressive disorder (MDD) is a highly prevalent psychiatric condition characterized by complex neurobiological mechanisms, including oxidative stress and neuroinflammation, with microglial activation playing a key role in its pathophysiology. Conventional antidepressants, though widely used, often fail to achieve remission due to limited efficacy, adverse effects, and poor patient adherence. In this context, nanotechnology-based drug delivery systems have emerged as promising strategies to overcome pharmacological limitations, enhance blood–brain barrier (BBB) penetration, and target neuroinflammatory pathways. This narrative review explores the role of microglia as both mediators of neuroinflammation and potential therapeutic targets in MDD. We examine different nanocarriers and their ability to modulate microglial activation, promote a shift from a pro-inflammatory (M1) to an anti-inflammatory (M2) phenotype, and enhance antidepressant efficacy. Preclinical studies have demonstrated that nanoparticle-based systems not only improve drug bioavailability and brain targeting but also potentiate neuroprotective effects by reducing oxidative stress, promoting neurogenesis, and restoring synaptic plasticity. These findings highlight the potential of nanotechnology as a novel approach to precision neuropsychopharmacology. This review aims to provide an integrative perspective on how nanocarrier-based strategies targeting microglia could redefine future therapeutic paradigms for MDD. Full article

Memory function is susceptible to decline with age, stress, and neurological diseases, highlighting the importance of exploring effective and sustainable strategies to enhance memory consolidation. Epinephrine plays a key role in memory consolidation; acute, moderate elevations enhance memory, while chronic high levels are inhibitory. Given the limitations of pharmacological interventions, this study aims to investigate exercise as a non-pharmacological means to promote post-learning memory consolidation by inducing acute epinephrine release, focusing on its mechanisms and optimized implementation strategies. This narrative review systematically reviews evidence from neurophysiology, molecular biology, and behavioral experiments and finds that exercise can safely and controllably activate the sympathetic–adrenal system, leading to a rapid rise in epinephrine. The release kinetics align highly with the critical time window for memory consolidation. Moderate-intensity aerobic exercise implemented within 30 min post-learning can significantly improve memory retention. The mechanisms involve not only epinephrine enhancing synaptic plasticity and LTP by activating hippocampal β-adrenergic receptors, but also synergistic effects across multiple systems, such as promoting osteocalcin signaling, upregulating BDNF expression, inducing neurogenesis, and optimizing cerebral metabolism and blood flow. Evidence suggests that exercise, as a non-pharmacological intervention, significantly enhances post-learning memory consolidation through the precise modulation of epinephrine release and multi-system synergy, offering both high efficacy and safety. Future research should focus on developing precise exercise prescriptions based on individual characteristics and leveraging wearable devices and digital technologies to improve intervention adherence and applicability, promoting its widespread use in educational and clinical settings. Full article

Traumatic brain injury (TBI) causes cortical dysfunction by increasing oxidative stress, neuroinflammation, apoptosis, and mitochondrial dysregulation, and impairing neurotrophic signaling and neurogenesis. This systematic review aimed to evaluate the effectiveness of exercise training on cortical molecular dysregulation and motor function in post-TBI. Following PRISMA 2020 guidelines, PubMed, EMBASE, and Web of Science were searched up to August 2025. Of 1173 records, 35 studies involving exercise training in post-TBI animal models were included. Exercise training protocols included voluntary wheel running, treadmill running, and swimming, with durations ranging from 7 to 63 days. Study quality was assessed using the CAMARADES checklist. Exercise training increased cortical glutathione and Na⁺/K⁺-ATPase activity and reduced oxidative stress in post-TBI. It reduced microglial, astrocytic reactivity, and pro-inflammatory markers, including IL-1β and TNF-α expression in post-TBI. It also reduced caspase activity while increasing heat shock protein 20 (HSP20), thereby downregulating cortical apoptosis in post-TBI. It enhanced motor function, cortical neurogenesis, and neurotrophic factors signaling, including BDNF, in post-TBI. Exercise training improved motor function and cortical neuroprotection by reducing oxidative stress, neuroinflammation, and apoptosis, while enhancing neurotrophic signaling and neurogenesis in post-TBI rodents, but the regulation of let-7c, IL-6, and mitochondrial function remained unclear. (PROSPERO: CRD420251073725) Full article