Lotte J Herstel scite author profile

Background: In an early stage of Alzheimer’s disease (AD), before the formation of amyloid plaques, neuronal network hyperactivity has been reported in both patients and animal models. This suggests an underlying disturbance of the balance between excitation and inhibition. Several studies have highlighted the role of somatic inhibition in early AD, while less is known about dendritic inhibition. Objective: In this study we investigated how inhibitory synaptic currents are affected by elevated Aβ levels. Methods: We performed whole-cell patch clamp recordings of CA1 pyramidal neurons in organotypic hippocampal slice cultures after treatment with Aβ-oligomers and in hippocampal brain slices from AppNl - F - G mice (APP-KI). Results: We found a reduction of spontaneous inhibitory postsynaptic currents (sIPSCs) in CA1 pyramidal neurons in organotypic slices after 24 h Aβ treatment. sIPSCs with slow rise times were reduced, suggesting a specific loss of dendritic inhibitory inputs. As miniature IPSCs and synaptic density were unaffected, these results suggest a decrease in activity-dependent release after Aβ treatment. We observed a similar, although weaker reduction in sIPSCs in CA1 pyramidal neurons from APP-KI mice compared to control. When separated by sex, the strongest reduction in sIPSC frequency was found in slices from male APP-KI mice. Consistent with hyperexcitability in pyramidal cells, dendritically targeting interneurons received slightly more excitatory input. GABAergic action potentials had faster kinetics in APP-KI slices. Conclusion: Our results show that Aβ affects dendritic inhibition via impaired action potential driven release, possibly due to altered kinetics of GABAergic action potentials. Reduced dendritic inhibition may contribute to neuronal hyperactivity in early AD.

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Network control through coordinated inhibition

Herstel

Wierenga

2021

Current Opinion in Neurobiology

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Quantitative mapping of transcriptome and proteome dynamics during polarization of human iPSC-derived neurons

Lindhout

Kooistra

Portegies

et al. 2020

Preprint

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Early neuronal development is a well-coordinated process in which neuronal stem cells differentiate into polarized neurons. This process has been well studied in classical non-human model systems, but to what extent this is recapitulated in human neurons remains unclear. To study neuronal polarization in human neurons, we cultured human iPSC-derived neurons, characterized early developmental stages, measured electrophysiological responses, and systematically profiled transcriptomic and proteomic dynamics during these steps. We found extensive remodeling of the neuron transcriptome and proteome, with altered mRNA expression of ~1,100 genes and different expression profiles of ~1,500 proteins during neuronal differentiation and polarization. We also identified a distinct stage in axon development marked by an increase in microtubule remodeling and apparent relocation of the axon initial segment from the distal to proximal axon. Our comprehensive characterization and quantitative map of transcriptome and proteome dynamics provides a solid framework for studying polarization in human neurons.(FOM, #16NEPH05, CJW). AUTHOR CONTRIBUTIONSFWL, RK and SP designed the research, conducted experiments, and wrote the article together with LJH. RS conducted and analyzed the mass spectrometry experiments supervised by MA, LJH performed and interpreted the electrophysiology data supervised by CJW, RK and BLS provided and interpreted the RNA sequencing analysis. HDM edited the article. CCH designed the experimental plan, supervised the research and wrote the article.

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Using SuperClomeleon to Measure Changes in Intracellular Chloride during Development and after Early Life Stress

Herstel

Peerboom

Uijtewaal

et al. 2022

eNeuro

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Quantitative mapping of transcriptome and proteome dynamics during polarization of human iPSC-derived neurons

Lindhout

Kooistra

Portegies

et al. 2020

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The differentiation of neuronal stem cells into polarized neurons is a well-coordinated process which has mostly been studied in classical non-human model systems, but to what extent these findings are recapitulated in human neurons remains unclear. To study neuronal polarization in human neurons, we cultured hiPSC-derived neurons, characterized early developmental stages, measured electrophysiological responses, and systematically profiled transcriptomic and proteomic dynamics during these steps. The neuron transcriptome and proteome shows extensive remodeling, with differential expression profiles of ~1100 transcripts and ~2200 proteins during neuronal differentiation and polarization. We also identified a distinct axon developmental stage marked by the relocation of axon initial segment proteins and increased microtubule remodeling from the distal (stage 3a) to the proximal (stage 3b) axon. This developmental transition coincides with action potential maturation. Our comprehensive characterization and quantitative map of transcriptome and proteome dynamics provides a solid framework for studying polarization in human neurons.

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Lotte J Herstel

Reduction of Dendritic Inhibition in CA1 Pyramidal Neurons in Amyloidosis Models of Early Alzheimer’s Disease

Network control through coordinated inhibition

Quantitative mapping of transcriptome and proteome dynamics during polarization of human iPSC-derived neurons

Using SuperClomeleon to Measure Changes in Intracellular Chloride during Development and after Early Life Stress

Quantitative mapping of transcriptome and proteome dynamics during polarization of human iPSC-derived neurons

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