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Пишет bioRxiv Subject Collection: Neuroscience (![[info]](http://lj.rossia.org/img/syndicated.gif){kind=small} syn_bx_neuro)@ 2025-07-29 15:45:00 |
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The Alzheimer's disease risk gene SORL1 is a regulator of excitatory neuronal function
Background: Synaptic dysfunction is an early feature of Alzheimer's disease (AD) and a significant contributor to cognitive decline and neurodegeneration. Proper localization of proteins involved in pre-and post-synaptic composition is dependent on endosomal recycling and trafficking. Alterations in trafficking complexes, such as retromer, have been shown to impair neuronal synaptic function. The SORL1 gene has been strongly implicated in AD pathogenesis and its protein product, SORLA, is an endosomal receptor that works in conjunction with retromer to regulate endosomal recycling. Methods: We utilized our established human induced pluripotent stem cell (hiPSC) derived excitatory cortical neuron model to examine SORL1's role in synaptic protein composition and neuronal function. We used Quantitative Multiplex co-Immunoprecipitation (QMI), a mesoscale. proteomics assay to measure synaptic protein interactions, immunocytochemistry to assay synapses and AMPA receptor subunits, and multi-electrode arrays (MEAs) to measure neuronal function of SORL1 KO and isogenic control hiPSC derived neurons. Results: We show that loss of SORL1 expression significantly changes many synaptic protein-protein interactions and patterns of expression. We demonstrate that SORL1 deficient neurons are hyperactive and that the increased activity is driven by glutamatergic neurotransmission. Hyperexcitability has been seen in other models of AD with familial AD variants in amyloid precursor protein and presenilin genes, due to the increases in amyloid beta (Ab) peptides. In the case of SORL1 deficiency, the hyperexcitability we observe is primarily due to mis-trafficking of synaptic proteins, rather than an overall increase in Ab. Finally, we find that SORL1 deficient neurons have impaired synaptic plasticity. Conclusions: These findings further support a growing body of literature implicating early endosomal recycling defects as drivers of AD pathogenesis. Furthermore, our work supports further emphasis on exploring the SORL1-retromer pathway for therapeutic development in AD.
Background: Synaptic dysfunction is an early feature of Alzheimer's disease (AD) and a significant contributor to cognitive decline and neurodegeneration. Proper localization of proteins involved in pre-and post-synaptic composition is dependent on endosomal recycling and trafficking. Alterations in trafficking complexes, such as retromer, have been shown to impair neuronal synaptic function. The SORL1 gene has been strongly implicated in AD pathogenesis and its protein product, SORLA, is an endosomal receptor that works in conjunction with retromer to regulate endosomal recycling. Methods: We utilized our established human induced pluripotent stem cell (hiPSC) derived excitatory cortical neuron model to examine SORL1's role in synaptic protein composition and neuronal function. We used Quantitative Multiplex co-Immunoprecipitation (QMI), a mesoscale. proteomics assay to measure synaptic protein interactions, immunocytochemistry to assay synapses and AMPA receptor subunits, and multi-electrode arrays (MEAs) to measure neuronal function of SORL1 KO and isogenic control hiPSC derived neurons. Results: We show that loss of SORL1 expression significantly changes many synaptic protein-protein interactions and patterns of expression. We demonstrate that SORL1 deficient neurons are hyperactive and that the increased activity is driven by glutamatergic neurotransmission. Hyperexcitability has been seen in other models of AD with familial AD variants in amyloid precursor protein and presenilin genes, due to the increases in amyloid beta (Ab) peptides. In the case of SORL1 deficiency, the hyperexcitability we observe is primarily due to mis-trafficking of synaptic proteins, rather than an overall increase in Ab. Finally, we find that SORL1 deficient neurons have impaired synaptic plasticity. Conclusions: These findings further support a growing body of literature implicating early endosomal recycling defects as drivers of AD pathogenesis. Furthermore, our work supports further emphasis on exploring the SORL1-retromer pathway for therapeutic development in AD.
