Nataliya Golovyashkina scite author profile

Dendritic spines represent the major postsynaptic input of excitatory synapses. Loss of spines and changes in their morphology correlate with cognitive impairment in Alzheimer’s disease (AD) and are thought to occur early during pathology. Therapeutic intervention at a preclinical stage of AD to modify spine changes might thus be warranted. To follow the development and to potentially interfere with spine changes over time, we established a long term ex vivo model from organotypic cultures of the hippocampus from APP transgenic and control mice. The cultures exhibit spine loss in principal hippocampal neurons, which closely resembles the changes occurring in vivo, and spine morphology progressively changes from mushroom-shaped to stubby. We demonstrate that spine changes are completely reversed within few days after blocking amyloid-β (Aβ) production with the gamma-secretase inhibitor DAPT. We show that the microtubule disrupting drug nocodazole leads to spine loss similar to Aβ expressing cultures and suppresses DAPT-mediated spine recovery in slices from APP transgenic mice. Finally, we report that epothilone D (EpoD) at a subnanomolar concentration, which slightly stabilizes microtubules in model neurons, completely reverses Aβ-induced spine loss and increases thin spine density. Taken together the data indicate that Aβ causes spine changes by microtubule destabilization and that spine recovery requires microtubule polymerization. Moreover, our results suggest that a low, subtoxic concentration of EpoD is sufficient to reduce spine loss during the preclinical stage of AD.

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Region-specific dendritic simplification induced by Aβ, mediated by tau via dysregulation of microtubule dynamics: a mechanistic distinct event from other neurodegenerative processes

Golovyashkina

Penazzi

Ballatore

et al. 2015

Mol Neurodegeneration

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BackgroundDendritic simplification, a key feature of the neurodegenerative triad of Alzheimer’s disease (AD) in addition to spine changes and neuron loss, occurs in a region-specific manner. However, it is unknown how changes in dendritic complexity are mediated and how they relate to spine changes and neuron loss.ResultsTo investigate the mechanisms of dendritic simplification in an authentic CNS environment we employed an ex vivo model, based on targeted expression of enhanced green fluorescent protein (EGFP)-tagged constructs in organotypic hippocampal slices of mice. Algorithm-based 3D reconstruction of whole neuron morphology in different hippocampal regions was performed on slices from APPSDL-transgenic and control animals. We demonstrate that induction of dendritic simplification requires the combined action of amyloid beta (Aβ) and human tau. Simplification is restricted to principal neurons of the CA1 region, recapitulating the region specificity in AD patients, and occurs at sites of Schaffer collateral input. We report that γ-secretase inhibition and treatment with the NMDA-receptor antagonist, CPP, counteract dendritic simplification. The microtubule-stabilizing drug epothilone D (EpoD) induces simplification in control cultures per se. Similar morphological changes were induced by a phosphoblocking tau construct, which also increases microtubule stability. In fact, low nanomolar concentrations of naturally secreted Aβ decreased phosphorylation at S262 in a cellular model, a site which is known to directly modulate tau-microtubule interactions.ConclusionsThe data provide evidence that dendritic simplification is mechanistically distinct from other neurodegenerative events and involves microtubule stabilization by dendritic tau, which becomes dephosphorylated at certain sites. They imply that treatments leading to an overall decrease of tau phosphorylation might have a negative impact on neuronal connectivity.

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DMSO modulates CNS function in a preclinical Alzheimer's disease model

et al. 2017

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DMSO has a widespread use as a vehicle for water-insoluble therapeutic drug candidates but may also exert disease-relevant pharmacological effects by itself. However, its influence on the CNS has hardly been addressed. Here we examined the brain structure and function following chronic exposure to low DMSO dose at a paradigm with flawed synaptic connectivity in a preclinical transgenic mouse model for Alzheimer's disease (APP mice). DMSO treatment increased spine density in a region-specific manner in the hippocampus of APP mice ex vivo and in vivo. Moreover, DMSO exhibited clear influence on the behavior of this mouse line by enhancing hippocampal-dependent spatial memory accuracy, modulating hippocampal-independent olfactory habituation and displaying anxiolytic effect. Despite that most of the action of DMSO was observed in animals with elevated Aβ levels, the drug did not exert its function via decreasing the oligomeric Aβ species. However, challenging organotypic hippocampal slice cultures with NMDA receptor antagonist MK-801 recapitulated the effect of DMSO on spine density, indicating a tuning influence of DMSO on receptor signalization. Our findings demonstrate that DMSO should be considered as a true bioactive compound, which has the potential to be a beneficial adjuvant to counteract Aβ-mediated synaptotoxicity and behavioral impairment.

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High-Resolution Imaging and Evaluation of Spines in Organotypic Hippocampal Slice Cultures

Sündermann

Golovyashkina

Tackenberg

et al. 2012

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Dendritic spines act as sites of excitatory neuronal input in many types of neurons. Spine shape correlates with the strength and maturity of synaptic contacts. Thus, evaluation of spine morphology is relevant for studies on neuronal development, for determination of morphological correlates of learning and memory, and for analysis of mechanisms of neurodegeneration. Here, we describe a method to determine spine morphology in an ex vivo model of organotypic hippocampal slice cultures prepared from transgenic or non-transgenic mice. Spines are imaged using confocal high-resolution imaging and evaluated by algorithm-based analysis. The approach permits semiautomated determination of spine density and classification of different spine types in dendritic segments from hippocampal subregions to evaluate intrahippocampal connectivity.

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