3D electron tomography of brain tissue unveils distinct Golgi structures that sequester cytoplasmic contents in neurons

Macroautophagy is morphologically characterized by autophagosome formation. Autophagosomes are double-membraned vesicles that sequester cytoplasmic components for further degradation in the lysosome. Basal autophagy is paramount for intracellular quality control in post-mitotic cells but, surprising...

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Veröffentlicht in:	Journal of cell science 2017-01, Vol.130 (1), p.83-89
Hauptverfasser:	Fernandez-Fernandez, Maria Rosario, Ruiz-Garcia, Desire, Martin-Solana, Eva, Chichon, Francisco Javier, Carrascosa, Jose L, Fernandez, Jose-Jesus
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Architecture Autophagy Brain Brain - ultrastructure Cryopreservation Degradation Electron Microscope Tomography - methods Electrons Endosomes Freezing Golgi apparatus Golgi Apparatus - metabolism Golgi Apparatus - ultrastructure Imaging, Three-Dimensional Lysosomes Mice, Inbred C57BL Neuroimaging Neurons Neurons - metabolism Neurons - ultrastructure Phagocytosis Phagosomes Preservation Proteolysis Proteolytic enzymes Quality control Rodents Three dimensional analysis Tomography
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container_title	Journal of cell science
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creator	Fernandez-Fernandez, Maria Rosario Ruiz-Garcia, Desire Martin-Solana, Eva Chichon, Francisco Javier Carrascosa, Jose L Fernandez, Jose-Jesus
description	Macroautophagy is morphologically characterized by autophagosome formation. Autophagosomes are double-membraned vesicles that sequester cytoplasmic components for further degradation in the lysosome. Basal autophagy is paramount for intracellular quality control in post-mitotic cells but, surprisingly, the number of autophagosomes in post-mitotic neurons is very low, suggesting that alternative degradative structures could exist in neurons. To explore this possibility, we have examined neuronal subcellular architecture by performing three-dimensional (3D) electron tomography analysis of mouse brain tissue that had been preserved through high-pressure freezing. Here, we report that sequestration of neuronal cytoplasmic contents occurs at the Golgi complex in distinct and dynamic structures that coexist with autophagosomes in the brain. These structures are composed of several concentric double-membraned layers that appear to be formed simultaneously by the direct bending and sealing of discrete Golgi stacks. These structures are labelled for proteolytic enzymes, and lysosomes and late endosomes are found in contact with them, leading to the possibility that the sequestered material could be degraded inside them. Our findings highlight the key role that 3D electron tomography, together with tissue rapid-freezing techniques, will have in gaining new knowledge about subcellular architecture.
doi_str_mv	10.1242/jcs.188060
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Autophagosomes are double-membraned vesicles that sequester cytoplasmic components for further degradation in the lysosome. Basal autophagy is paramount for intracellular quality control in post-mitotic cells but, surprisingly, the number of autophagosomes in post-mitotic neurons is very low, suggesting that alternative degradative structures could exist in neurons. To explore this possibility, we have examined neuronal subcellular architecture by performing three-dimensional (3D) electron tomography analysis of mouse brain tissue that had been preserved through high-pressure freezing. Here, we report that sequestration of neuronal cytoplasmic contents occurs at the Golgi complex in distinct and dynamic structures that coexist with autophagosomes in the brain. These structures are composed of several concentric double-membraned layers that appear to be formed simultaneously by the direct bending and sealing of discrete Golgi stacks. These structures are labelled for proteolytic enzymes, and lysosomes and late endosomes are found in contact with them, leading to the possibility that the sequestered material could be degraded inside them. 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subjects	Animals Architecture Autophagy Brain Brain - ultrastructure Cryopreservation Degradation Electron Microscope Tomography - methods Electrons Endosomes Freezing Golgi apparatus Golgi Apparatus - metabolism Golgi Apparatus - ultrastructure Imaging, Three-Dimensional Lysosomes Mice, Inbred C57BL Neuroimaging Neurons Neurons - metabolism Neurons - ultrastructure Phagocytosis Phagosomes Preservation Proteolysis Proteolytic enzymes Quality control Rodents Three dimensional analysis Tomography
title	3D electron tomography of brain tissue unveils distinct Golgi structures that sequester cytoplasmic contents in neurons
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