Topic: Synaptic Dysfunction

ePoster
7 ePosters
Seminar
4 seminars

Latest

SeminarNeuroscience

Synaptic molecules: Linking synaptic dysfunction to neuropsychiatric disorders

Jinye Dai
Stanford University, USA
Feb 1, 2022
SeminarNeuroscience

Dysfunctional synaptic vesicle recycling – links to epilepsy

Mike Cousin
University of Edinburgh
Dec 1, 2021

Accurate and synchronous neurotransmitter release is essential for brain communication and occurs when neurotransmitter-containing synaptic vesicles (SVs) fuse to release their content in response to neuronal activity. Neurotransmission is sustained by the process of SV recycling, which generates SVs locally at the presynapse. Until relatively recently it was believed that most mutations in genes that were essential for SV recycling would be incompatible with life, due to this fundamental role. However, this is not the case, with mutations in essential genes for SV fusion, retrieval and recycling identified in individuals with epilepsy. This seminar will cover our laboratory’s progress in determining how genetic mutations in people with epilepsy translate into presynaptic dysfunction and ultimately into seizure activity. The principal focus of these studies will be in vitro investigations of, 1) the biological role of these gene products and 2) how their dysfunction impacts SV recycling, using live fluorescence imaging of genetically-encoded reporters. The gene products to be discussed in more detail will be the SV protein SV2A, the protein kinase CDKL5 and the translation repressor FMRP.

SeminarNeuroscienceRecording

Microglia function and dysfunction in Alzheimer’s disease

Beth Stevens
Harvard Medical School
Oct 8, 2020

Emerging genetic studies of late-onset Alzheimer’s Disease implicate the brain’s resident macrophages in the pathogenesis of AD. More than half the risk genes associated with late-onset AD are selectively expressed in microglia and peripheral myeloid cells; yet we know little about the underlying biology or how myeloid cells contribute to AD pathogenesis. Using single-cell RNA sequencing and spatial transcriptomics we identified molecular signatures that can be used to localize and monitor distinct microglia functional states in the human and mouse brain. Our results show that microglia assume diverse functional states in development, aging and injury, including populations corresponding to known microglial functions including proliferation, migration, inflammation, and synaptic phagocytosis. We identified several innate immune pathways by which microglia recognize and prune synapses during development and in models of Alzheimer’s disease, including the classical complement cascade. Illuminating the mechanisms by which developing synaptic circuits are sculpted is providing important insight on understanding how to protect synapses in Alzheimer’s and other neurodegenerative diseases of synaptic dysfunction.

SeminarNeuroscience

The cellular phase of Alzheimer’s Disease: from genes to cells

Bart De Strooper
UK Dementia Research Institute, UCL, London & & KU Leuven & VIB Center for Brain and Disease Research, Belgium KU Leuven & VIB Center for Brain and Disease Research, Belgium
Oct 1, 2020

The amyloid cascade hypothesis for Alzheimer disease ((Hardy and Selkoe, 2002; Hardy and Higgins, 1992; Selkoe, 1991), updated in (Karran et al., 2011) provides a linear model for the pathogenesis of AD with Aβ accumulation upstream and Tau pathology, inflammation, synaptic dysfunction, neuronal loss and dementia downstream, all interlinked, initiated and driven by Aβ42 peptides or oligomers. The genetic mutations causing familial Alzheimer disease seem to support this model. The nagging problem remains however that the postulated causal, and especially the ’driving’ role of abnormal Aβ aggregation or Aβ oligomer formation could not be convincingly demonstrated until now. Indeed, many questions (e.g. what causes Aβ toxicity, what is the relation between Aβ and Tau pathology, what causes neuronal death, why is amyloid deposition not correlated with dementia etc…) were already raised when the amyloid hypothesis was conceived 25 years ago. These questions remain in essence unanswered. It seems that the old paradigm is not tenable: the amyloid cascade is too linear, too neurocentric, and does not take into account the long time lag between the biochemical phase i.e. the appearance of amyloid plaques and neuronal tangles and the ultimate clinical phase, i.e. the manifestation of dementia. The pathways linking these two phases must be complex and tortuous. We have called this the cellular phase of AD (De Strooper and Karran, 2016) to suggest that a long period of action and reaction involving neurons, neuronal circuitry but also microglia, astroglia, oligodendrocytes, and the vasculature underlies the disease. In fact it is this long disease process that should be studied in the coming years. While microglia are part of this process, they should not be considered as the only component of the cellular phase. We expect that further clinical investigations and novel tools will allow to diagnose the effects of the cellular changes in the brain and provide clinical signs for this so called preclinical or prodromal AD. Furthermore the better understanding of this phase will lead to completely novel drug targets and treatments and will lead to an era where patients will receive an appropriate therapy according to their clinical stage. In this view anti-amyloid therapy is probably only effective and useful in the very early stage of the disease and AD does no longer equal to dementia. We will discuss in our talk how single cell technology and transplantation of human iPS cells into mouse brain allow to start to map in a systematic way the cellular phase of Alzheimer’s Disease.

ePosterNeuroscience

Acute genetic elimination of a synaptic co-chaperone to study and to revert presynaptic dysfunction and neurodegeneration

Fátima Rubio-Pastor, Santiago López-Begines, Nozha Borjini, Pablo García-Junco-Clemente, Rafael Fernández-Chacón
ePosterNeuroscience

Directly reprogrammed medium spiny neurons for studying pathology and synaptic dysfunction in Huntington's disease in vitro model

Nina Kraskovskaia
ePosterNeuroscience

The emerging role of microRNAs in experimental and clinical multiple sclerosis: implications for inflammation-driven synaptic dysfunctions and disease course

Francesca De Vito, Alessandra Musella, Francesca Romana Rizzo, Sara Balletta, Diego Fresegna, Antonietta Gentile, Livia Guadalupi, Mario Stampanoni Bassi, Luana Gilio, Valerio Licursi, Alessandro Moscatelli, Colleen Patricia Ryan, Fabio Buttari, Silvia Caioli, Valentina Vanni, Krizia Sanna, Antonio Bruno, Ettore Dolcetti, Diego Centonze, Georgia Mandolesi
ePosterNeuroscience

Impaired spatial navigation and age-dependent hippocampal synaptic dysfunction accompanied by a chronic inflammatory cytokine profile in db/db mice

Mohammed Al-Onaizi, Ahmad Al-Sarraf, Fatema Kazem, Kawthar Braysh, Muddanna Rao, Narayana Kilarkaje
ePosterNeuroscience

miRNA-186-5p – a new culprit of chronic stress-induced synaptic dysfunction

Beatriz F. Rodrigues, Mariline Silva, Paulo Pinheiro, Ana Luisa Carvalho
ePosterNeuroscience

Polyphenol derivative exerts anti-epileptic effects through acute activation of JNK pathway in Drosophila and mitigates the synaptic dysfunctions associated with epilepsy in rodents

Shefali Mishra, Vijaya Verma, Manish K. Dwivedi, Pooja Jorwal, Varun Gowda, Madavan Vasudevan, Sujit K. Sikdar, Vimlesh Kumar, James P. Clement, Upendra Nongthomba
ePosterNeuroscience

Reactive Astrocytosis and Synaptic Dysfunction in Polyamine Catabolism Activation

Sarah Amato, Chiara Cervetto, Monica Averna, Laura Vergani, Marco Pedrazzi, Giulio Matteucci, Paolo Mariottini, Manuela Cervelli, Manuela Marcoli

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