Articles tagged with Synapse Formation
A new study reveals that astrocytes actively participate in motor-learning circuit rewiring by eliminating synapses in the striatum. The research identifies MEGF10 as a key molecular mediator of this process, which is regulated by dopamine signaling and neural activity.
A new MIT study reveals that somatostatin-expressing neurons follow a unique trajectory when forming connections in the visual cortex, establishing conditions needed for sensory refinement. These inhibitory neurons help usher in the critical period by setting baseline inhibition levels.
Researchers from Kyushu University found that the brain forms new, high-density clusters of synapses on specific segments of dendrites during adolescence, challenging the 'adolescent synaptic pruning' hypothesis. This discovery may offer new hope for understanding the biological basis of schizophrenia and other neurodevelopmental condi...
A study in mice confirms the presence of two molecules that enable precise connection between inhibitory interneurons and target excitatory neurons. This link regulates information processing and maintains balance in brain circuits, with implications for understanding neuronal disorders such as schizophrenia and autism.
A recent study published in Nature Communications reveals that the mechanical properties of the developing brain play a significant role in synapse formation and electrical signal emergence. The researchers found that softer regions exhibit higher synapse densities, while stiffer regions show lower densities.
A new study by MIT neuroscientists reveals that circular RNA, specifically circHomer1, strongly influences how neurons build circuit connections during visual system development. Knocking out circHomer1 prevents synapse maturation and delays expected neural adjustments in response to monocular deprivation.
Researchers at MIT's Picower Institute have revealed a fundamental model for how neural activity during development builds properly working connections. Neural activity plays a crucial role in maturing synaptic active zones, allowing them to send the right amount of chemical signals at the right times.
Scientists at UCSF successfully used CRISPRa to increase SCN2A levels in mice with the genetic disorder, resulting in reduced seizures and improved brain function. The therapy offers hope for treating neurodevelopmental issues related to SCN2A haploinsufficiency.
Scientists discovered a precise communication system in the gut, where telocytes deliver signals directly to intestinal stem cells using fine extensions. This finding challenges long-standing assumptions about gut healing and repair, potentially leading to better treatments for conditions like IBD and colon cancer.
A study published in Nature Communications reveals that neurons in mice brain rewire and refine their connections to integrate visual signals from both eyes over a 10-day period. The researchers found that only 40% of the initial synapses survived, with 24% added and 27% removed, indicating an extensive process of synaptic turnover.
A study in mice reveals that only 40% of synapses survive during critical development, with active spines more likely to endure. Clustering of spines also emerges, allowing them to combine activity and enhance visual processing.
Researchers have identified a four-amino-acid mini-exon in the PTPδ gene that plays a critical role in brain development and behavior. The study found that deleting this mini-exon led to anxiety-like behavior and reduced movement in mice, highlighting its essential role in maintaining synaptic balance.
Researchers at VIB-KU Leuven have identified a novel protein complex that regulates the formation of spine apparatus in developing synapses, essential for stabilizing mature synapses and supporting learning and memory. The study reveals that GPR158 interacts with PLCXD2 to control spine apparatus abundance, lifting the brake on synapti...
Researchers at USC Dornsife College of Letters, Arts and Sciences have developed a powerful new method for selectively and reversibly breaking connections between brain cells, targeting specific synapses without harming neurons. The technique, inspired by the brain's own system for recycling proteins, allows for the elimination of eith...
Researchers developed a computational model that reproduces intricate protein structures at postsynaptic densities, crucial sites for learning and memory. The model reveals details on how these proteins organize into unique structures through liquid-liquid phase separation, enabling sustained activation of downstream signaling pathways.
Researchers at Lancaster University are developing high-performance memory devices using self-assembled molecular technology to overcome the von Neumann bottleneck in computing. The Memristive Organometallic Devices (MemOD) project aims to deliver faster, more stable, and energy-efficient AI hardware.
Researchers at Arizona State University propose a unifying explanation for Alzheimer’s disease, focusing on the role of chronic stress granules in disrupting gene activity. The condition causes massive changes in gene expression, affecting every known neuropathology and clinical manifestation.
Researchers explore the role of efferocytosis in reducing inflammation and containing injury spread after an ischemic stroke. Efferocytosis may offer a promising therapeutic strategy to promote neural regeneration and minimize brain damage.
Researchers link neuropilin2 gene to autism and seizure development, highlighting its role in regulating neural circuits. The study suggests targeting specific phases of neuronal development could lead to therapeutic interventions for individuals with autism.
The study found decreased NMDA receptors in synapses and increased extrasynaptic membranes in Alzheimer's patients, suggesting neuronal toxicity-related activity. The novel protocol allows for precise analysis of these receptors in human postmortem brains, paving the way for new therapeutic approaches.
Researchers studied mossy fiber synapses in the hippocampus, a crucial region for memory formation and spatial navigation. They discovered that specific proteins play key roles in encoding and processing distinguishing features to trigger memory retrieval.
A team of scientists has identified a new genetic mutation in the SGIP1 gene that may cause early-onset Parkinsonism. The mutation affects brain cell communication, leading to synaptic dysfunction and recessive Parkinsonism. This discovery provides new insights into the disease's development and potential treatment strategies.
Researchers uncover the importance of kainate receptors in enabling synaptic plasticity and transmission in the cerebellum. The study's findings have significant implications for understanding neurological disorders and developing new treatments.
Researchers at Colorado State University used human stem cells to study synaptic connections in the brain, focusing on GABAergic synapses. They found that Gephyrin promotes autonomous assembly of these synapses, which can develop independently of neuronal communication. This understanding could lead to new treatments for neurological d...
A team of Harvard researchers, led by Jeff Lichtman, has created the largest synaptic-resolution, 3D reconstruction of a piece of human brain to date. The dataset contains 1,400 terabytes of data on neural connections in a tiny piece of human temporal cortex.
A team of researchers from Tokyo Institute of Technology identified the molecular mechanisms involved in synaptic communication using Drosophila. They found that Side-IV/Beat-IIb immunoglobulin superfamily protein molecules play a crucial role in inducing synapse formation and regulating preferential signaling among neuron pairs.
Researchers at Kobe University identified differences in synaptic protein production between mice and marmosets during development. The study found that these differences may relate to evolutionary differences between rodent and primate brains, as well as their relevance to autism spectrum disorders.
The Kobe University discovery identifies a new key player for synaptic function, revealing that the poorly characterized protein FAM81A interacts with at least three major postsynaptic proteins and modulates their condensation. The absence of this protein leads to a significant decrease in activity in cultured neurons.
A KAIST research team has developed a technique called SynapShot, which allows for the real-time observation of synapse formation, extinction, and alterations. This breakthrough technique uses fluorescent proteins to track changes in synapses, offering new insights into brain function and potentially revolutionizing neurological research.
Researchers discovered that a little-understood synapse in the brain plays a pivotal role in producing myelin, the protective sheath around nerve cells. This finding could lead to new therapies for multiple sclerosis, neurodegenerative conditions and brain cancer.
Neuronal activity stimulates gene expression in human brain cells by influencing transcription factors and chromatin modifiers, particularly CREB and CBP. The interaction between CREB and DNA requires prior acetylation mediated by CBP to activate gene expression.
A newly developed labeling method allows for visualization of intraregional synaptic connections between inhibitory interneurons and excitatory engram cells. Researchers have identified the role of inhibitory interneurons in memory expression, suggesting that they suppress fear expression by inhibiting fear engram cells.
A team of scientists has shed light on how synapses are formed by identifying a shared transport pathway involving motor proteins and unique organelles. This discovery could lead to new therapeutic approaches for neurological disorders and improve understanding of neuronal regeneration.
A study by researchers at the University of Tokyo found that the presynaptic Ube3a E3 ligase molecule plays a key role in eliminating neural synapses. This discovery offers insights into developmental disorders such as Angelman syndrome and autism spectrum disorders.
A study published in Brain Behavior and Immunity found autoantibodies against a synaptic adhesion protein, neurexin 1α, in patients with schizophrenia. In mice, these autoantibodies caused schizophrenia-related changes, including reduced social behavior and cognitive function.
The gene LRRC4 regulates synapse formation, stability and excitatory transmission, playing a crucial role in learning, memory formation and storage. It also has key implications in neuronal disorders and aggressive brain and spinal cord cancer.
Researchers found that an extra copy of a gene controlling synapse formation causes excessive inhibitory signaling in the brain of mice with Down syndrome. This may contribute to conditions such as autism, epilepsy, and bipolar disorder.
A team of researchers used imaging technology to study synapse dynamics in the brains of live mice, revealing that some new synapses formed during fear conditioning are eliminated over time. This finding supports the 'unlearning' hypothesis and could help scientists better understand brain activity in patients with PTSD.
Researchers have successfully grown retinal cells from stem cells that can connect with neighboring cells and transmit sensory information like healthy ones. The breakthrough could lead to human clinical trials to treat degenerative eye disorders such as retinitis pigmentosa and age-related macular degeneration.
The HUSH complex is involved in normal brain development, neuronal individuality, and connectivity. The complex also regulates repetitive-like gene clusters, including protocadherin gene clusters, which are essential for neuron-to-neuron interactions.
A University of Ottawa research team has made new discoveries on how motor skills are learned and stored in the brain. By studying mice, they found that a specific transcription factor called NPAS4 regulates gene changes in inhibitory neurons, leading to the formation of learning-associated neuron ensembles.
Researchers at HHMI's Janelia Research Campus have discovered a new type of synapse between neurons and their primary cilia, which allows for long-term changes in the cell's chromatin. This discovery could help scientists better understand how cells communicate and may lead to the development of more selective medications.
The study reveals that top-down information from the higher-order motor cortex to the primary motor cortex is crucial for motor learning, while newly formed synapses in the thalamus store acquired motor memories. This challenge to the widely held view suggests a two-step process for motor skill learning.
Researchers at Colorado State University have found a way to alter the type of synapses between brain cells using enzymes. This breakthrough could lead to new treatments for brain disorders caused by faulty synaptic information processing and exchange.
Researchers found that unpredictable parental behaviors disrupt optimal brain circuit formation in children, leading to increased vulnerability to mental illness and substance abuse. Studies using mice and human infants suggest that predictable signals and environments are crucial for healthy brain development.
A new study suggests that supplementing a diet with Ascidiacea, also known as sea squirts, reverses some main signs of aging in animal models. The researchers found that plasmalogens, vital to body processes, decrease with age and contribute to neurodegenerative diseases like Alzheimer's and Parkinson's.
Researchers at Shinshu University have elucidated a new molecular mechanism controlling the survival of cerebral nerve cells. Neurexin regulates cerebellar granule cell survival independently of synapses, playing a crucial role in neurodevelopmental disorders such as autism and schizophrenia.
Scientists at the University of California San Diego have discovered that planar cell polarity is a widely used mechanism for forming and maintaining glutamatergic synapses. The study found that Prickle protein plays a crucial role in stabilizing these synapses, which are essential for neuronal communication.
Researchers at NICT unraveled a neural correlate of Pavlovian conditioning, discovering that alteration in information processing by feeding command neurons governs behavioral change. The experimental system made possible real-time observation of cell-cell connection for memory formation.
Researchers at Max Planck Florida Institute have identified IgSF11 as a key molecule mediating layer-specific synaptic targeting in cortical Chandelier Cells. This discovery reveals that IgSF11 confers specificity through homophilic interaction, enabling the precise connection of inhibitory interneurons with target neurons.
Researchers found that astrocytes play a critical role in forming synapses in response to cocaine exposure, which can contribute to addiction. Blocking these synapses may help prevent relapse, suggesting a new therapeutic target for substance use disorder.
Researchers from Peter the Great Saint-Petersburg Polytechnic University found a substance that reduces the negative effect of mutations in genes related to neuronal contact formation. The discovery suggests promising compounds for anti-Alzheimer's drugs.
As cells age, their ability to remove damaged proteins and structures declines, leading to a buildup of waste inside neurons. Researchers discovered that restoring autophagy in aged neurons can restore protein disposal, providing insight into potential therapeutic targets for neurodegenerative diseases.
A team of scientists at VIB and KU Leuven has discovered a key role for Prl-1 phosphatase in specifying the formation of neuronal circuits in the brain. The discovery, made using a genetic single-cell approach in fruit flies, sheds light on how complex brain patterns develop during early development.
Researchers have discovered genetic switches that ignite axon formation, revealing the role of PTBP2 and SHTN1 genes. The study shows how alternative splicing enables neurons to produce long axons, essential for neural communication.
A team led by W. Christopher Risher discovered that the α2δ-1 receptor is necessary for synapse structure and brain connectivity, implicating astrocyte-to-neuron signaling in psychiatric disorders such as autism and addiction.
A biochemical reconstitution approach demonstrated that multivalent interaction networks formed by major PSD scaffold proteins lead to formation of PSD-like assemblies via phase separation. These assemblies can cluster receptors, concentrate enzymes, and promote actin bundle formation.
Researchers found that high homocysteine levels in mice lead to increased tau tangles, nerve cell death, and impaired learning and memory. The study suggests a potential link between hyperhomocysteinemia and neurodegenerative diseases, highlighting the need for further investigation into the role of 5-lipoxygenase in disease progression.
Researchers have identified an asymmetric role for pre-synaptic cadherin/catenin complexes in stabilizing post-synaptic spines. This finding challenges the long-held assumption of symmetry in synaptogenesis and has implications for understanding neurodevelopmental disorders such as autism spectrum disorder.
The Gruber Foundation has awarded $1.5 million to three top scientists for their groundbreaking work in cosmology, genetics and neuroscience. Sandra Faber, Stephen Elledge, and Joshua Sanes have been recognized for their pioneering research on galaxy structure, DNA damage response pathway, and synapse formation.