Impairment and Restoration of Homeostatic Plasticity in Cultured Cortical Neurons From a Mouse Model of Huntington Disease

Smith-Dijak, Amy; Nassrallah, Wissam B.; Zhang, Lily Y. J.; Geva, Michal; Hayden, Michael R.; Raymond, Lynn A.

doi:10.3389/fncel.2019.00209

Cited by 45 publications

(55 citation statements)

References 55 publications

(141 reference statements)

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“…The reduction in spine density was found to be reversible in D2-MSN but not in in D1-MSN [21][22][23]. Dendritic pruning, in contrast, was not reversible [8]. This indicates that reversibility requirements may differ between D1 and D2 MSN and between spine density and TDL.…”

Section: Introductionmentioning

confidence: 84%

“…For instance, D2-MSN are disinhibited by dopamine depletion. The homeostatic response in the face of chronic dopamine depletion includes a decrease in electrical excitability and a reduced number of glutamatergic synapses [8]. A lower density of dendritic spines and a pruned dendritic tree was also observed in further animal models [9,[13][14][15][16][17][18] and in striatal MSN of PD patients [19,20].…”

Section: Introductionmentioning

confidence: 88%

“…Homeostatic plasticity allows neuronal networks to maintain a stable rate of activity when synapses change [5]. This has been studied mainly during development and learning [5,6], but also in the course of neurological and psychiatric diseases [7][8][9][10]. In humans and animal models, chronic dopaminergic depletion and substitution can induce plastic changes that differ from acute effects and that are potentially mediated by homeostatic plasticity mechanisms.…”

Section: Introductionmentioning

confidence: 99%

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Changes in Striatal Medium Spiny Neuron Morphology Resulting from Dopamine Depletion Are Reversible

Witzig

Komnig

Falkenburger

2020

Cells

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The classical motor symptoms of Parkinson’s disease (PD) are caused by degeneration of dopaminergic neurons in the substantia nigra, which is followed by secondary dendritic pruning and spine loss at striatal medium spiny neurons (MSN). We hypothesize that these morphological changes at MSN underlie at least in part long-term motor complications in PD patients. In order to define the potential benefits and limitations of dopamine substitution, we tested in a mouse model whether dendritic pruning and spine loss can be reversible when dopaminergic axon terminals regenerate. In order to induce degeneration of nigrostriatal dopaminergic neurons we used the toxicity of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) in C57BL/6J mice; 30 mg/kg MPTP was applied i.p. on five consecutive days. In order to assess the consequences of dopamine depletion, mice were analyzed 21 days after the last injection. In order to test reversibility of MSN changes we exploited the property of this model that striatal axon terminals regenerate by sprouting within 90 days and analyzed a second cohort 90 days after MPTP. Degeneration of dopaminergic neurons was confirmed by counting TH-positive neurons in the substantia nigra and by analyzing striatal catecholamines. Striatal catecholamine recovered 90 days after MPTP. MSN morphology was visualized by Golgi staining and quantified as total dendritic length, number of dendritic branch points, and density of dendritic spines. All morphological parameters of striatal MSN were reduced 21 days after MPTP. Statistical analysis indicated that dendritic pruning and the reduction of spine density represent two distinct responses to dopamine depletion. Ninety days after MPTP, all morphological changes recovered. Our findings demonstrate that morphological changes in striatal MSN resulting from dopamine depletion are reversible. They suggest that under optimal conditions, symptomatic dopaminergic therapy might be able to prevent maladaptive plasticity and long-term motor complications in PD patients.

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Section: Introductionmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Changes in Striatal Medium Spiny Neuron Morphology Resulting from Dopamine Depletion Are Reversible

Witzig

Komnig

Falkenburger

2020

Cells

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“…BDNF overexpression is sufficient to rescue many phenotypic characteristics of YAC128 HD mice (e.g., motor performance, cognitive deficits, synaptic density) (Xie et al, 2010), further suggesting that BDNF signaling could be an important contributor to neuroprotection following S1R activation. The idea that some of the beneficial effects of pridopidine in HD models can be mediated through BDNF signaling was supported by recent experimental evidence from Smith-Dijak et al (2019). Synaptic scaling was suppressed in YAC128 cultures, as determined by recording the amplitude and frequency of mEPSCs after blockade of activity-dependent neurotransmission with TTX.…”

Section: Pridopidine’s Mechanism Of Action In the Treatment Of Hdmentioning

confidence: 95%

Neuronal Sigma-1 Receptors: Signaling Functions and Protective Roles in Neurodegenerative Diseases

et al. 2019

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Sigma-1 receptor (S1R) is a multi-functional, ligand-operated protein situated in endoplasmic reticulum (ER) membranes and changes in its function and/or expression have been associated with various neurological disorders including amyotrophic lateral sclerosis/frontotemporal dementia, Alzheimer’s (AD) and Huntington’s diseases (HD). S1R agonists are broadly neuroprotective and this is achieved through a diversity of S1R-mediated signaling functions that are generally pro-survival and anti-apoptotic; yet, relatively little is known regarding the exact mechanisms of receptor functioning at the molecular level. This review summarizes therapeutically relevant mechanisms by which S1R modulates neurophysiology and implements neuroprotective functions in neurodegenerative diseases. These mechanisms are diverse due to the fact that S1R can bind to and modulate a large range of client proteins, including many ion channels in both ER and plasma membranes. We summarize the effect of S1R on its interaction partners and consider some of the cell type- and disease-specific aspects of these actions. Besides direct protein interactions in the endoplasmic reticulum, S1R is likely to function at the cellular/interorganellar level by altering the activity of several plasmalemmal ion channels through control of trafficking, which may help to reduce excitotoxicity. Moreover, S1R is situated in lipid rafts where it binds cholesterol and regulates lipid and protein trafficking and calcium flux at the mitochondrial-associated membrane (MAM) domain. This may have important implications for MAM stability and function in neurodegenerative diseases as well as cellular bioenergetics. We also summarize the structural and biochemical features of S1R proposed to underlie its activity. In conclusion, S1R is incredibly versatile in its ability to foster neuronal homeostasis in the context of several neurodegenerative disorders.

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“…This idea is supported by the association between decreased cortical expression of Kalirin‐7, a guanine‐nucleotide exchange factor involved in maintenance of dendritic spines, and development of a cognitive phenotype in HD model mice (Puigdellívol et al, ). If indeed impaired HSP contributes to cognitive deficits in HD, then treatment with pridopidine may provide additional benefits in ameliorating such symptoms, since it restores HSP at glutamatergic cortical synapses in cultures from HD mice (Smith‐Dijak et al, ). Further investigation of impairment of HSP in HD may shed more light on the mechanisms underlying these symptoms, and the pathogenesis of HD more generally.…”

Section: Glutamatementioning

confidence: 99%

Alterations in synaptic function and plasticity in Huntington disease

Smith-Dijak

Sepers

Raymond

2019

Journal of Neurochemistry

Self Cite

102

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Huntington disease (HD) is an inherited neurodegenerative disorder caused by an expansion of the CAG repeat region in the first exon of the huntingtin gene. Neurodegeneration, which begins in the striatum and then spreads to other brain areas, is preceded by dysfunction in multiple aspects of neurotransmission across a variety of brain areas. This review will provide an overview of the neurochemical mediators and modulators of synaptic transmission that are disrupted in HD. This includes classical neurotransmitters like glutamate and gamma‐aminobutyric acid, modulators such as dopamine, adenosine and endocannabinoids, and molecules like brain‐derived neurotrophic factor which affect neurotransmission in a more indirect manner. Alterations in the functioning of these signaling pathways can occur across multiple brain regions such as striatum, cortex and hippocampus, and affect transmission and plasticity at the synapses within these regions, which may ultimately change behaviour and contribute to the pathophysiology of HD. The current state of knowledge in this area has already yielded useful information about the causes of synaptic dysfunction and selective cell death. A full understanding of the mechanisms and consequences of disruptions in synaptic function and plasticity will lend insight into the development of the symptoms of HD, and potential drug targets for ameliorating them.

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Impairment and Restoration of Homeostatic Plasticity in Cultured Cortical Neurons From a Mouse Model of Huntington Disease

Cited by 45 publications

References 55 publications

Changes in Striatal Medium Spiny Neuron Morphology Resulting from Dopamine Depletion Are Reversible

Changes in Striatal Medium Spiny Neuron Morphology Resulting from Dopamine Depletion Are Reversible

Neuronal Sigma-1 Receptors: Signaling Functions and Protective Roles in Neurodegenerative Diseases

Alterations in synaptic function and plasticity in Huntington disease

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