Search Results (121)

Background: Extracellular vesicles (EVs) mediate intercellular communication in the central nervous system and are a major source of biomarkers. This study characterizes the EV-derived proteome secreted by human endothelial brain cells (HEBCs), astrocytes, and neurons to identify cell-specific roles in intercellular communication in the brain. Methods: Mass spectrometry analyses of EVs and corresponding parent cells were performed to identify differentially enriched proteins. Gene Ontology (GO) analysis of statistically significant, abundantly expressed proteins between EVs and parent cells (log₂ fold-change ≥ 2.0, p < 0.05) was performed to assess cell-specific functions. Results: Proteome analysis identified on average 932 proteins in astrocyte EVs (versus 1725 in parent cells), 1040 in HEBC EVs (versus 5451 in parent cells), and 470 in neuronal EVs (versus 578 in parent cells). The analysis indicated that astrocytes had the highest number of significantly abundant proteins (118), followed by HEBCs (24) and neurons (25). Astrocyte EVs were enriched in lipoproteins, complement factors, and protease inhibitors; HEBCs EVs in tight junction proteins, adhesion molecules, and protease regulators; and neuronal EVs in chromatin-associated histones, tubulin isoforms, and RNA-binding proteins. Conclusions: The proteomic signatures of EVs from different neurovascular unit cells suggest specialized roles in blood–brain barrier homeostasis, immune regulation, and synaptic and epigenetic signaling under healthy conditions. These baseline signatures provide a framework for future studies to investigate how brain cell-derived EVs may contribute to neurodegenerative disorders. Full article

Listeria monocytogenes (Lm) is an important zoonotic foodborne pathogen that causes severe rhombencephalitis in ruminants. The trigeminal ganglion is a critical node for Lm invasion of the central nervous system via neural pathways. However, the roles of key virulence factors InlA, InlB, and LLO from ovine-derived Lm in trigeminal ganglion neuron infection remain unclear. In this study, LM90SB2, an ovine-derived Lm strain isolated from a sheep with encephalitis in Xinjiang, China, was used as the wild type, and its ΔInlAB double-gene deletion and ΔInlABO triple-gene deletion mutants were constructed. Primary mouse trigeminal ganglion cells (TGCs) were infected with these strains, and cell-association and invasion assays, bacterial colonization analysis, cell scratch tests, Western blotting, and qRT-PCR were performed to explore the effects of InlA, InlB, and LLO on Lm infection of TGCs and their regulatory roles in host adhesion molecules N-cadherin and NCAM1. The results showed that the wild-type LM90SB2 had significantly stronger cell-association, invasion, and colonization abilities in TGCs than the ΔInlAB and ΔInlABO mutants (p < 0.01 or p < 0.0001). LM90SB2 infection significantly upregulated the mRNA and protein expression levels of N-cadherin and NCAM1 in TGCs and enhanced TGC migration, while these effects were gradually attenuated with the sequential deletion of InlA, InlB and LLO. This study clarifies the synergistic roles of InlA, InlB, and LLO in mediating the infection of trigeminal ganglion neurons by ovine-derived Lm and reveals the molecular mechanism by which Lm promotes neural invasion by regulating the expression of host cell adhesion molecules. Our findings provide important experimental data for elucidating the neural invasion pathway of Lm in ruminants and lay a theoretical foundation for the development of targeted prevention and control strategies for ruminant listeriosis in veterinary clinical practices. Full article

The neuronal cell adhesion molecule NrCAM is widely expressed in the nervous system across the lifespan and has important physiological functions in the development of neuronal circuits through axonal growth and guidance and formation and maintenance of synapses in the cortex. NrCAM gene polymorphisms are associated with vulnerability to neuropsychiatric disorders such as schizophrenia, as well as vulnerability to substance use disorders. We investigated the effects of acute and chronic stress and the effects of systemic administration of AMPAR antagonist CNQX and NMDAR antagonist MK-801 on delay discounting in male NrCAM knockout (KO) mice and their wild-type littermate controls (WT). Under the no-stress condition, no discounting differences were found. Acute stress increased discounting and impulsivity in WTs but not in NrCAM KO mice. Chronic stress increased discounting and impulsivity in both genotypes. CNQX increased impulsive choice in WT controls but not in NrCAM KOs; impulsive choice decreased in both genotypes after MK-801 administration. Relative to WTs, NrCAM KOs had more neuronal activation in the prelimbic and orbitofrontal cortices. In NrCAM KO mice, a low dose of MK-801 decreased neuronal activation in the ventral orbitofrontal cortex and increased activation in the accumbens shell and core. These results indicate differential effects of genotype, stress, and response to glutamatergic drugs and support a role for NrCAM in stress-induced behavioral alterations relevant to addiction and psychiatric disorders. Full article

There is increasing evidence that exposure to environmental toxicants may impact fertility, especially during critical windows of reproductive axis development. Hypothalamic gonadotropin-releasing hormone (GnRH) neurons, essential for puberty onset and fertility, originate from the olfactory placode and migrate toward the hypothalamus during development, making them particularly vulnerable to environmental insults. Cadmium (Cd), a widespread heavy metal, is well known for its gonadotoxicity, but its impact on human hypothalamic neuron development remains unclear. Using human fetal GnRH neuroblasts (FNCB4) we investigated the effects of Cd exposure on their morpho-functional and developmental features. Cd induced oxidative stress and COX2 mRNA upregulation, indicative of inflammatory pathway activation, which was accompanied by reduced cell migration and downregulation of motility-related genes. These effects were associated with F-actin disassembly and altered expression of adhesion molecules. Electrophysiological analyses showed that Cd altered membrane potential, increased capacitance and permeability, and disrupted gap junctional communication, as also confirmed by connexin-43 delocalization. Moreover, Cd significantly reduced the expression of specific GnRH neuronal markers, suggesting impaired functional maturation. Overall, our findings provide the first evidence that Cd may interfere with mechanisms crucially involved in human GnRH neuron development, adding new mechanistic insights into the comprehension of how early-life exposure to Cd may contribute to fertility concerns. Full article

Neuronal synapses are the functional units of communication in the central nervous system. This review describes the molecular mechanisms regulating synaptic transmission, plasticity, and circuit refinement. At the presynaptic active zone, scaffolding proteins including bassoon, piccolo, RIMs, and munc13 organize vesicle priming and the localization of voltage-gated calcium channels. Neurotransmitter release is mediated by the SNARE complex, comprising syntaxin-1, SNAP25, and synaptobrevin, and triggered by the calcium sensor synaptotagmin-1. Following exocytosis, synaptic vesicles are recovered through clathrin-mediated, ultrafast, bulk, or kiss-and-run endocytic pathways. Postsynaptically, the postsynaptic density (PSD) serves as a protein hub where scaffolds such as PSD-95, shank, homer, and gephyrin anchor excitatory (AMPA, NMDA) and inhibitory (GABA-A, Glycine) receptors are observed. Synaptic strength is modified during long-term potentiation (LTP) and depression (LTD) through signaling cascades involving kinases like CaMKII, PKA, and PKC, or phosphatases such as PP1 and calcineurin. These pathways regulate receptor trafficking, Arc-mediated endocytosis, and actin-dependent remodeling of dendritic spines. Additionally, synapse formation and elimination are guided by cell adhesion molecules, including neurexins and neuroligins, and by microglial pruning via the complement cascade (C1q, C3) and “don’t eat me” signals like CD47. Molecular diversity is further expanded by alternative splicing and post-translational modifications. A unified model of synaptic homeostasis is required to understand the basis of neuropsychiatric and neurological disorders. Full article

The expression of polysialic acid (polySia) on the neuronal cell adhesion molecule (NCAM) is called NCAM-polysialylation, which is strongly related to the migration and invasion of tumor cells and aggressive clinical status. During the NCAM polysialylation process, polysialyltransferases (polySTs), such as polysialyltransferase IV (ST8SIA4) or polysialyltransferase II (ST8SIA2), can catalyze the addition of CMP-sialic acid (CMP-Sia) to the NCAM to form polysialic acid (polySia). In this study, the docking models of polysialyltransferase IV (ST8Sia4) protein and different ligands were predicted using Alphafold 3 and DiffDock servers, and the prediction accuracy was further verified using the NMR experimental spectra of the interactions between polysialyltransferase domain (PSTD), a crucial peptide domain in ST8Sia4, and a different ligand. This combination strategy provides new insights into a quick and effective screening for inhibitors of tumor cell migration. Full article

Objective: Neuronal growth regulator 1 (Negr1) is a GPI-anchored neuronal cell adhesion molecule of the IgLON superfamily associated with multiple psychiatric disorders. This study aimed to investigate behavioral and molecular adaptations to social isolation (SI) stress in Negr1-deficient (Negr1^−/−) mice. Methods: Male and female Negr1^−/− and wild-type (Wt) mice (n = 10 per group) were exposed to two weeks of SI or group housing (Ctl). Behavioral assays assessed exploratory and anxiety-like behavior. Gene expression analyses in the prefrontal cortex and hippocampus were performed using RT-qPCR, focusing on GABAergic, neurotrophic, and IgLON family genes. Results: SI-induced weight loss in Negr1^−/− mice compared to Wt was evident in both sexes but more pronounced in males. Behaviorally, SI Wt males showed stress-induced hyperactivity compared to Ctl Wt, whereas SI Negr1^−/− males exhibited blunted exploratory behavior relative to SI Wt in the open field test (OFT). Negr1^−/− females showed reduced exploration in the elevated plus maze (EPM), suggesting increased anxiety. Hippocampal Pvalb was downregulated in SI Negr1^−/− mice of both sexes compared to Wts, with a stronger decrease in males, indicating heightened male vulnerability in GABAergic interneuron function. In males, SI reduced hippocampal Bdnf in both genotypes, whereas Ntrk2 (TrkB) upregulation occurred only in Negr1^−/− mice, suggesting a genotype-specific compensatory response. Hippocampal expression of Fgfr2 and IgLON members (Ntm1a/1b, Lsamp1a/1b) was increased in SI Negr1^−/− males compared to SI Wt, with minimal changes in females. Conclusions: Negr1 deficiency leads to sex-specific behavioral and molecular adaptations to social isolation stress, highlighting the role of Negr1 in modulating neurotrophic and GABAergic signaling pathways under adverse environmental conditions. Full article

The brain and the immune system communicate in many ways and interact directly at neuroimmune interfaces at brain borders, such as hippocampus, choroid plexus, and gateway reflexes. The first part of this review described intercellular communication (synapses, extracellular vesicles, and tunneling nanotubes) during homeostasis and neuroimmunomodulation upon dysfunction. This second part compares spatial orientation, learning, and memory function in both systems. The hippocampus, deep in the medial temporal lobes of the brain, is reported to play a central role in all three functions. Its medial entorhinal cortex contains neuronal spatial cells (place cells, head direction cells, boundary vector cells, and grid cells) that facilitate spatial navigation and allow the construction of cognitive maps. Sensory input (about 100 megabytes per second) via engram neurons and top down and bottom up information processing between the temporal lobes and other lobes of the brain are described to facilitate learning and memory function. Output impulses leave the brain via approximately 1.5 million fibers, which connect to effector organs such as muscles and glands. Spatial orientation in the immune system is described to involve gradients of chemokines, chemokine receptors, and cell adhesion molecules. These facilitate immune cell interactions with other cells and the extracellular matrix, recirculation via lymphatic organs (lymph nodes, thymus, spleen, and bone marrow), and via lymphatic fluid, blood, cerebrospinal fluid, and tissues. Learning in the immune system is summarized to include recognition of exogenous antigens from the outside world as well as endogenous blood-borne antigens, including tumor antigens. This learning process involves cognate interactions through immune synapses and the distinction between self and non-self antigens. Immune education via vaccination helps the process of development of protective immunity. Examples are presented concerning the therapeutic potential of memory T cells, in particular those derived from bone marrow. Like in the brain, memory function in the immune system is described to be facilitated by priming (imprinting), training, clonal cooperation, and an integrated perception of objects. The discussion part highlights evolutionary aspects. Full article

Prostate stem cell antigen (PSCA) is a Ly6/uPAR protein that targets neuronal nicotinic acetylcholine receptors (nAChRs). It exists in membrane-tethered and soluble forms, with the latter upregulated in Alzheimer’s disease. We hypothesize that PSCA may be linked to a wider spectrum of neurological diseases and could induce neuroinflammation. Indeed, PSCA expression is significantly upregulated in the brain of patients with multiple sclerosis, Huntington’s disease, Down syndrome, bipolar disorder, and HIV-associated dementia. To investigate PSCA’s structure, pharmacology, and inflammatory function, we produced a correctly folded water-soluble recombinant analog (ws-PSCA). In primary hippocampal neurons and astrocytes, ws-PSCA differently regulates secretion of inflammatory factors and adhesion molecules and induces pro-inflammatory responses by increasing TNFβ secretion. Heteronuclear NMR and ¹⁵N relaxation measurements reveal a classical β-structural three-finger fold with conformationally disordered loops II and III. Positive charge clustering on the molecular surface suggests the functional importance of ionic interactions by these loops. Electrophysiological studies in Xenopus oocytes point on ws-PSCA inhibition of α3β2-, high-, and low-sensitive variants of α4β2- (IC₅₀ ~50, 27, and 15 μM, respectively) but not α4β4-nAChRs, suggesting targeting of the β2 subunit. Ensemble docking and molecular dynamics simulations predict PSCA binding to high-sensitive α4β2-nAChR at α4/β2 and β2/β2 interfaces. Complexes are stabilized by ionic and hydrogen bonds between PSCA’s loops II and III and the primary and complementary receptor subunits, including glycosyl groups. This study gives new structural and functional insights into PSCA’s interaction with molecular targets and provides clues to understand its role in the brain function and mental disorders. Full article

AMOG/β₂, the β₂ isoform of the sodium pump (Na⁺/K⁺-ATPase), functions as an adhesion molecule on glial cells, mediating critical neuron–astrocyte interactions during central nervous system (CNS) development. Despite its established role in glial adhesion, the neuronal receptor that partners with AMOG/β₂ remains unknown. This review examines the structural and functional properties of AMOG/β₂, including its capacity to form trans-dimers, both homophilic and potentially heterophilic—drawing comparisons with the β₁ subunit, a well-characterized adhesion molecule. By integrating computational modeling, in vitro data, and structural predictions, we explore how factors such as N-glycosylation and cis-membrane interactions influence β₂-mediated adhesion. We further consider candidate neuronal partners, including TSPAN31 and RTN4, and speculate on their potential roles in mediating heterophilic AMOG/β₂ interactions. Finally, we discuss the broader implications of AMOG/β₂ in neuron–glia communication, synaptic organization, neurodevelopment, and CNS disorders such as glioblastoma. Identifying the binding partner of AMOG/β₂ holds promise not only for understanding the molecular basis of CNS adhesion but also for uncovering novel mechanisms of neuroglial regulation in health and disease. Full article

After spinal cord injury, pathological changes predominantly proceed caudal to the site of injury. To what extent these changes contribute to abnormalities during regeneration is poorly understood. Here, we addressed this question with a low-thoracic compression injury mouse model. The total numbers of immunohistochemically stained neuronal and glial cell types in the lumbar spinal cord were stereologically determined 6 weeks after injury. We also investigated injured mice deficient in close homolog of L1 (CHL1), which had been reported to recover better after injury than their wild-type littermates. We here report that there were no differences between genotypes in uninjured animals. In both injured CHL1-deficient and wild-type littermates, gray and white matter volumes were decreased as compared with uninjured mice. Numbers of motoneurons and parvalbumin-expressing interneurons were also reduced in both genotypes. Numbers of interneurons in injured mutant mice were lower than in wild-type littermates. Whereas injury did not affect numbers of astrocytes and oligodendrocytes in the gray matter, numbers of microglia/macrophages were increased. In the mutant white matter, numbers of oligodendrocytes were reduced, with no changes in numbers of astrocytes and microglia. A loss of motoneurons and interneurons was observed in both genotypes, but loss of interneurons was more prominent in the absence of CHL1. We propose that, after injury, CHL1 deficiency causes deficits in structural outcome not seen after injury of wild-type mice. Full article

The L1 molecule is a cell adhesion molecule (L1CAM) that was originally implicated in neuronal development. In recent years, studies of several large cohorts of patients with endometrial cancer have revealed that L1CAM acts as a poor prognostic factor, in most cases independent of other parameters. It seems to be an important factor, especially in the non-specific molecular profile subgroup (p53 normal expression, MMR proficient, POLE not mutated) of endometrial cancer, and a factor predictive of the response to chemotherapy. This review aims to gather most of the current knowledge regarding this promising prognostic factor. Full article

Background/Objectives: The bidirectional selection of the Roman low- (RLA) and Roman high-avoidance (RHA) rat strains for extremely slow vs. very rapid acquisition of the two-way (shuttle-box) avoidance response has generated two divergent phenotypic profiles: RHA rats exhibit a behavioural pattern and gene expression profile in the frontal cortex and hippocampus (HPC) that are relevant to social and attentional/cognitive schizophrenia-linked symptoms; on the other hand, RLA rats display phenotypic traits linked to increased anxiety and sensitivity to stress-induced depression-like behaviours. The present studies aimed to evaluate the enduring and potentially positive effects of neonatal handling-stimulation (NH) on the traits differentiating these two strains of rats. Methods: We evaluated the effects of NH on anxious behaviour, prepulse inhibition of startle (PPI), spatial working memory, and hormone responses to stress in adult rats of both strains. Furthermore, given the proposed involvement of neuronal/synaptic plasticity and neurotrophic factors in the development of anxiety, stress, depression, and schizophrenia-related symptoms, using Western blot (WB) we assessed the effects of NH on the content of brain-derived neurotrophic factor (BDNF), its trkB receptor and Polysialilated-Neural Cell Adhesion Molecule (PSA-NCAM), in the prefrontal cortex (PFC), anterior cingulate cortex (ACg), ventral (vHPC), and dorsal (dHPC) hippocampus of adult rats from both strains. Results: NH increased novelty-induced exploration and reduced anxiety, particularly in RLA rats, attenuated the stress-induced increment in corticosterone and prolactin plasma levels, and improved PPI and spatial working memory in RHA rats. These effects correlated to long-lasting increases of BDNF and PSA-NCAM content in PFC, ACg, and vHPC. Conclusions: Collectively, these findings show enduring and distinct NH effects on neuroendocrine and behavioural and cognitive processes in both rat strains, which may be linked to neuroplastic and synaptic changes in the frontal cortex and/or hippocampus. Full article

The axon initial segment (AIS) is a specialized subcellular domain that plays an essential role in action potential initiation and the diffusion barrier. A key organizer of the AIS is Ankyrin-G, a scaffolding protein responsible for clustering voltage-gated ion channels, cell adhesion molecules (CAMs), and cytoskeletal components at this critical neuronal domain. Recent proteomic analyses have revealed a complex network of proteins in the AIS, emphasizing Ankyrin-G’s central role in its molecular architecture. This review discusses new findings in the study of AIS-associated proteins. It explains how Ankyrin-G and its binding partners (such as ion channels, CAMs, spectrins, actin, and microtubule-associated proteins including end-binding protein 3, tripartite motif-containing protein 46, and calmodulin-regulated spectrin-associated protein 2) organize their structure. Understanding the dynamic regulation and molecular interactions within the AIS offers insights into neuronal excitability and reveals potential therapeutic targets for axonal dysfunction–related diseases. Through these dynamic interactions, Ankyrin-G ensures the proper alignment and dense clustering of key channel complexes, thereby maintaining the AIS’s distinctive molecular and functional identity. By further unraveling the complexity of Ankyrin-G’s interactome, our understanding of AIS formation, maintenance, and plasticity will be considerably enhanced, contributing to the elucidation of the pathogenesis of neurological and neuropsychiatric disorders. Full article

The young mammalian central nervous system regenerates after spinal cord injury and recovers locomotion, whereas adult mice only show limited recovery that depends on the injury severity, genetic background, and physical therapy. At the molecular level, key regulators that contribute to recovery are cell adhesion molecules, such as L1CAM (L1). At the cell surface, L1 functions as a homotypic receptor that signal-transduces crucial functions in neuronal migration and survival, neurite outgrowth, myelination, formation of synapses, and synaptic plasticity. In the adult central nervous system, L1 is expressed only by neurons. We now show that L1 is unexpectedly also expressed by 26% microglia, freshly isolated from a 7-day-old mouse brain. At postnatal day 21, only 3% of microglia are L1-positive. Using a mouse mutant in which L1 is deleted specifically in monocytes of 10- to 14-week-old mice, functional recovery was reduced up to 4 weeks after injury at lower thoracic spinal levels. Also, NF200-immunoreactive and 5-HT-immunoreactive fibers were found decreased below the injury site as compared to wild-type mice. In conclusion, microglial cells that express L1 stimulate neurite outgrowth in vitro, improve functional recovery after spinal cord injury in adult mice, and increase fiber densities caudal to the lesion site. Full article