scholarly journals Mitochondrial Structure and Polarity in Dendrites and the Axon Initial Segment Are Regulated by Homeostatic Plasticity and Dysregulated in Fragile X Syndrome

2021 ◽  
Vol 9 ◽  
Author(s):  
Pernille Bülow ◽  
Peter A. Wenner ◽  
Victor Faundez ◽  
Gary J. Bassell
Keyword(s):  
Fragile X Syndrome ◽  
Neurodevelopmental Disorders ◽  
Cortical Neurons ◽  
Initial Segment ◽  
Fragile X ◽  
Axon Initial Segment ◽  
Homeostatic Plasticity ◽  
Mitochondrial Morphology ◽  
Specific Regulation ◽  
And Function

Mitochondrial dysfunction has long been overlooked in neurodevelopmental disorders, but recent studies have provided new links to genetic forms of autism, including Rett syndrome and fragile X syndrome (FXS). Mitochondria show plasticity in morphology and function in response to neuronal activity, and previous research has reported impairments in mitochondrial morphology and function in disease. We and others have previously reported abnormalities in distinct types of homeostatic plasticity in FXS. It remains unknown if or how activity deprivation triggering homeostatic plasticity affects mitochondria in axons and/or dendrites and whether impairments occur in neurodevelopmental disorders. Here, we test the hypothesis that mitochondria are structurally and functionally modified in a compartment-specific manner during homeostatic plasticity using a model of activity deprivation in cortical neurons from wild-type mice and that this plasticity-induced regulation is altered in Fmr1-knockout (KO) neurons. We uncovered dendrite-specific regulation of the mitochondrial surface area, whereas axon initial segment (AIS) mitochondria show changes in polarity; both responses are lost in the Fmr1 KO. Taken together, our results demonstrate impairments in mitochondrial plasticity in FXS, which has not previously been reported. These results suggest that mitochondrial dysregulation in FXS could contribute to abnormal neuronal plasticity, with broader implications to other neurodevelopmental disorders and therapeutic strategies.

scholarly journals Mitochondrial Structure and Polarity in Dendrites and the Axon Initial Segment are Regulated by Homeostatic Plasticity and Dysregulated in Fragile X Syndrome

2021 ◽  
Author(s):  
Pernille Bülow ◽  
Peter A Wenner ◽  
Victor Faundez ◽  
Gary J Bassell
Keyword(s):  
Fragile X Syndrome ◽  
Neurodevelopmental Disorders ◽  
Neuronal Plasticity ◽  
Cortical Neurons ◽  
Initial Segment ◽  
Fragile X ◽  
Axon Initial Segment ◽  
Homeostatic Plasticity ◽  
Mitochondrial Morphology ◽  
And Function

Abstract Mitochondrial dysfunction has long been overlooked in neurodevelopmental disorders, but recent studies have provided new links to genetic forms of autism, including Rett syndrome and Fragile X Syndrome (FXS). In parallel, recent studies have uncovered important basic functions of mitochondria to power protein synthesis, synaptic plasticity and neuronal maturation. The mitochondrion also responds to neuronal activity by altering its morphology and function, and this plasticity of the mitochondrion appear important for proper neuronal plasticity. Previous research has reported disease induced changes in mitochondrial morphology and function, but it remains unknown how such abnormalities affect the ability of mitochondria to express activity dependent plasticity. This study addresses this gap in knowledge using a mouse model of FXS. We previously reported abnormalities in one type of homeostatic plasticity, called homeostatic intrinsic plasticity, which is known to involve structural changes in the axon initial segment (AIS). Another form of homeostatic plasticity, called synaptic scaling, which involves postsynaptic changes in dendrites, is also impaired in FXS. It remains unknown if or how homeostatic plasticity affects mitochondria in axons and/or dendrites and whether impairments occur in neurodevelopmental disorders. Here, we test the hypothesis that mitochondria are structurally and functionally modified in a compartment specific manner during homeostatic plasticity in cortical neurons from wild type mice, and that this plasticity-induced regulation is altered in Fmr1 KO neurons, as a model of FXS. We uncovered dendritic specific regulation of mitochondrial surface area, whereas AIS mitochondria show changes in polarity; both responses are lost in Fmr1 KO. Taken together our results demonstrate impairments in mitochondrial plasticity in FXS, which has not previously been reported. These results suggest that mitochondrial dysregulation in FXS contributes to abnormal neuronal plasticity, with broader implications to other neurodevelopmental disorders and therapeutic strategies.

scholarly journals Homeostatic plasticity rules control the wiring of axo-axonic synapses at the axon initial segment

2018 ◽  
Author(s):  
Alejandro Pan-Vazquez ◽  
Winnie Wefelmeyer ◽  
Victoria Gonzalez Sabater ◽  
Juan Burrone
Keyword(s):  
Initial Segment ◽  
Pyramidal Cells ◽  
Axon Initial Segment ◽  
Homeostatic Plasticity ◽  
Network Activity ◽  
Gabaergic Interneuron ◽  
Chandelier Cells ◽  
Local Circuits ◽  
And Function

AbstractGABAergic interneurons are chiefly responsible for controlling the activity of local circuits in the cortex1,2. However, the rules that govern the wiring of interneurons are not well understood3. Chandelier cells (ChCs) are a type of GABAergic interneuron that control the output of hundreds of neighbouring pyramidal cells through axo-axonic synapses which target the axon initial segment (AIS)4. Despite their importance in modulating circuit activity, our knowledge of the development and function of axo-axonic synapses remains elusive. In this study, we investigated the role of activity in the formation and plasticity of ChC synapses. In vivo imaging of ChCs during development uncovered a narrow window (P12-P18) over which axons arborized and formed connections. We found that increases in the activity of either pyramidal cells or individual ChCs during this temporal window resulted in a reversible decrease in axo-axonic connections. Voltage imaging of GABAergic transmission at the AIS showed that axo-axonic synapses were depolarising during this period. Identical manipulations of network activity in older mice (P40-P46), when ChC synapses are inhibitory, resulted in an increase in axo-axonic synapses. We propose that the direction of ChC plasticity follows homeostatic rules that depend on the polarity of axo-axonic synapses.

The behavioral neurogenetics of fragile X syndrome: Analyzing gene–brain–behavior relationships in child developmental psychopathologies

2003 ◽  
Vol 15 (4) ◽  
pp. 927-968 ◽  
Author(s):  
ALLAN L. REISS ◽  
CHRISTOPHER C. DANT
Keyword(s):  
Environmental Factors ◽  
Fragile X Syndrome ◽  
Neurodevelopmental Disorders ◽  
Fragile X ◽  
Single Gene ◽  
Structure And Function ◽  
Research Approach ◽  
And Function ◽  
And Behavior ◽  
Brain Behavior

Analyzing gene–brain–behavior linkages in childhood neurodevelopmental disorders, a research approach called “behavioral neurogenetics,” has provided new insights into understanding how both genetic and environmental factors contribute to complex variations in typical and atypical human development. Research into etiologically more homogeneous disorders, such as fragile X syndrome, in particular, allows the use of more precise metrics of genetic risk so that we can more fully understand the complex pathophysiology of childhood onset neurodevelopmental disorders. In this paper, we review our laboratory's behavioral neurogenetics research by examining gene–brain–behavior relationships in fragile X syndrome, a single-gene disorder that has become a well-characterized model for studying neurodevelopmental dysfunction in childhood. Specifically, we examine genetic influences, trajectories of cognition and behavior, variation in brain structure and function, and biological and environmental factors that influence developmental and cognitive outcomes of children with fragile X. The converging approaches across these multilevel scientific domains indicate that fragile X, which arises from disruption of a single gene leading to the loss of a specific protein, is associated with a cascade of aberrations in neurodevelopment, resulting in a central nervous system that is suboptimal with respect to structure and function. In turn, structural and functional brain alterations lead to early disruption in emotion, cognition, and behavior in the child with fragile X. The combination of molecular genetics, neuroimaging, and behavioral research have advanced our understanding of the linkages between genetic variables, neurobiological measures, IQ, and behavior. Our research and that of others demonstrates that neurobehavior and neurocognition, genetics, and neuroanatomy are all different views of the same intriguing biological puzzle, a puzzle that today is rapidly emerging into a more complete picture of the intricate linkages among gene, brain, and behavior in developing children. Understanding the complex multilevel scientific perspective involved in fragile X will also contribute to our understanding of normal development by highlighting developmental events throughout the life span, thereby helping us to delineate the boundaries of pathology.

scholarly journals Tropomyosin Tpm3.1 is required to maintain the structure and function of the axon initial segment

2019 ◽  
Author(s):  
Amr Abouelezz ◽  
Holly Stefen ◽  
Mikael Segerstråle ◽  
David Micinski ◽  
Rimante Minkeviciene ◽  
...  
Keyword(s):  
Actin Filaments ◽  
Hippocampal Neurons ◽  
Initial Segment ◽  
Actin Polymerization ◽  
Firing Frequency ◽  
Axon Initial Segment ◽  
Action Potential Initiation ◽  
Sodium Ion Channels ◽  
And Function ◽  
Filament Network

ABSTRACTThe axon initial segment (AIS) is the site of action potential initiation and serves as a vesicular filter and diffusion barrier that help maintain neuronal polarity. Recent studies have revealed details about a specialized structural complex in the AIS. While an intact actin cytoskeleton is required for AIS formation, pharmacological disruption of actin polymerization compromises the AIS vesicle filter but does not affect overall AIS structure. In this study, we found that the tropomyosin isoform Tpm3.1 decorates a population of relatively stable actin filaments in the AIS. Inhibiting Tpm3.1 in cultured hippocampal neurons led to the loss of AIS structure, the AIS vesicle filter, the clustering of sodium ion channels, and reduced firing frequency. We propose that Tpm3.1-decorated actin filaments form a stable actin filament network under the AIS membrane which provides a scaffold for membrane organization and AIS proteins.

scholarly journals Fragile X syndrome patient-derived neurons developing in the mouse brain show FMR1 -dependent phenotypes

2021 ◽  
Author(s):  
Marine A Krzisch ◽  
Hao A Wu ◽  
Bingbing Yuan ◽  
Troy W. Whitfield ◽  
X. Shawn Liu ◽  
...  
Keyword(s):  
Fragile X Syndrome ◽  
Neuronal Development ◽  
Fragile X ◽  
In Vitro Models ◽  
Synaptic Activity ◽  
Human Neurons ◽  
Induced Pluripotent ◽  
And Function ◽  
The Brain

Abnormal neuronal development in Fragile X syndrome (FXS) is poorly understood. Data on FXS patients remain scarce and FXS animal models have failed to yield successful therapies. In vitro models do not fully recapitulate the morphology and function of human neurons. Here, we co-injected neural precursor cells (NPCs) from FXS patient-derived and corrected isogenic control induced pluripotent stem cells into the brain of neonatal immune-deprived mice. The transplanted cells populated the brain and a proportion differentiated into neurons and glial cells. Single-cell RNA sequencing of transplanted cells revealed upregulated excitatory synaptic transmission and neuronal differentiation pathways in FXS neurons. Immunofluorescence analyses showed accelerated maturation of FXS neurons after an initial delay. Additionally, increased percentages of Arc- and Egr1-positive FXS neurons and wider dendritic protrusions of mature FXS striatal medium spiny neurons pointed to an increase in synaptic activity and synaptic strength as compared to control. This transplantation approach provides new insights into the alterations of neuronal development in FXS by facilitating physiological development of cells in a 3D context, and could be used to test new therapeutic compounds correcting neuronal development defects in FXS.

Fragile X syndrome

2020 ◽  
Vol 13 (12) ◽  
pp. 712-716
Author(s):  
Rebecca Dunphy
Keyword(s):  
Primary Care ◽  
Learning Disability ◽  
Fragile X Syndrome ◽  
Clinical Features ◽  
Neurodevelopmental Disorders ◽  
Fragile X ◽  
Healthcare Services ◽  
Diagnosis And Management ◽  
Genetic Causes

Fragile X syndrome is one of the most common genetic causes of learning disability. Patients with this and other neurodevelopmental disorders will often present to primary care before a diagnosis is made, and this can be challenging and worrying for patients and other carers. These patients may face a number of barriers in accessing healthcare services including communication, behavioural and sensory difficulties. It may be difficult to understand whether symptoms are part of their condition or because of a comorbidity that needs to be addressed. Input from families and carers can be vital in helping with diagnosis. This article aims to outline the key clinical features, diagnosis and management of this syndrome.

scholarly journals Cofilin and Actin Dynamics: Multiple Modes of Regulation and Their Impacts in Neuronal Development and Degeneration

Cells ◽  
2021 ◽  
Vol 10 (10) ◽  
pp. 2726
Author(s):  
James R. Bamburg ◽  
Laurie S. Minamide ◽  
O’Neil Wiggan ◽  
Lubna H. Tahtamouni ◽  
Thomas B. Kuhn
Keyword(s):  
Cortical Neurons ◽  
Hippocampal Neurons ◽  
Translational Regulation ◽  
Neuronal Development ◽  
Mitochondrial Fission ◽  
Amyloid Β ◽  
Cellular Prion Protein ◽  
Actin Dynamics ◽  
Specific Regulation ◽  
And Function

Proteins of the actin depolymerizing factor (ADF)/cofilin family are ubiquitous among eukaryotes and are essential regulators of actin dynamics and function. Mammalian neurons express cofilin-1 as the major isoform, but ADF and cofilin-2 are also expressed. All isoforms bind preferentially and cooperatively along ADP-subunits in F-actin, affecting the filament helical rotation, and when either alone or when enhanced by other proteins, promotes filament severing and subunit turnover. Although self-regulating cofilin-mediated actin dynamics can drive motility without post-translational regulation, cells utilize many mechanisms to locally control cofilin, including cooperation/competition with other proteins. Newly identified post-translational modifications function with or are independent from the well-established phosphorylation of serine 3 and provide unexplored avenues for isoform specific regulation. Cofilin modulates actin transport and function in the nucleus as well as actin organization associated with mitochondrial fission and mitophagy. Under neuronal stress conditions, cofilin-saturated F-actin fragments can undergo oxidative cross-linking and bundle together to form cofilin-actin rods. Rods form in abundance within neurons around brain ischemic lesions and can be rapidly induced in neurites of most hippocampal and cortical neurons through energy depletion or glutamate-induced excitotoxicity. In ~20% of rodent hippocampal neurons, rods form more slowly in a receptor-mediated process triggered by factors intimately connected to disease-related dementias, e.g., amyloid-β in Alzheimer’s disease. This rod-inducing pathway requires a cellular prion protein, NADPH oxidase, and G-protein coupled receptors, e.g., CXCR4 and CCR5. Here, we will review many aspects of cofilin regulation and its contribution to synaptic loss and pathology of neurodegenerative diseases.

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