@article{12174, abstract = {Vacuolar-type H+-ATPase (V-ATPase) is a multimeric complex present in a variety of cellular membranes that acts as an ATP-dependent proton pump and plays a key role in pH homeostasis and intracellular signalling pathways. In humans, 22 autosomal genes encode for a redundant set of subunits allowing the composition of diverse V-ATPase complexes with specific properties and expression. Sixteen subunits have been linked to human disease. Here we describe 26 patients harbouring 20 distinct pathogenic de novo missense ATP6V1A variants, mainly clustering within the ATP synthase α/β family-nucleotide-binding domain. At a mean age of 7 years (extremes: 6 weeks, youngest deceased patient to 22 years, oldest patient) clinical pictures included early lethal encephalopathies with rapidly progressive massive brain atrophy, severe developmental epileptic encephalopathies and static intellectual disability with epilepsy. The first clinical manifestation was early hypotonia, in 70%; 81% developed epilepsy, manifested as developmental epileptic encephalopathies in 58% of the cohort and with infantile spasms in 62%; 63% of developmental epileptic encephalopathies failed to achieve any developmental, communicative or motor skills. Less severe outcomes were observed in 23% of patients who, at a mean age of 10 years and 6 months, exhibited moderate intellectual disability, with independent walking and variable epilepsy. None of the patients developed communicative language. Microcephaly (38%) and amelogenesis imperfecta/enamel dysplasia (42%) were additional clinical features. Brain MRI demonstrated hypomyelination and generalized atrophy in 68%. Atrophy was progressive in all eight individuals undergoing repeated MRIs. Fibroblasts of two patients with developmental epileptic encephalopathies showed decreased LAMP1 expression, Lysotracker staining and increased organelle pH, consistent with lysosomal impairment and loss of V-ATPase function. Fibroblasts of two patients with milder disease, exhibited a different phenotype with increased Lysotracker staining, decreased organelle pH and no significant modification in LAMP1 expression. Quantification of substrates for lysosomal enzymes in cellular extracts from four patients revealed discrete accumulation. Transmission electron microscopy of fibroblasts of four patients with variable severity and of induced pluripotent stem cell-derived neurons from two patients with developmental epileptic encephalopathies showed electron-dense inclusions, lipid droplets, osmiophilic material and lamellated membrane structures resembling phospholipids. Quantitative assessment in induced pluripotent stem cell-derived neurons identified significantly smaller lysosomes. ATP6V1A-related encephalopathy represents a new paradigm among lysosomal disorders. It results from a dysfunctional endo-lysosomal membrane protein causing altered pH homeostasis. Its pathophysiology implies intracellular accumulation of substrates whose composition remains unclear, and a combination of developmental brain abnormalities and neurodegenerative changes established during prenatal and early postanal development, whose severity is variably determined by specific pathogenic variants.}, author = {Guerrini, Renzo and Mei, Davide and Szigeti, Margit Katalin and Pepe, Sara and Koenig, Mary Kay and Von Allmen, Gretchen and Cho, Megan T and McDonald, Kimberly and Baker, Janice and Bhambhani, Vikas and Powis, Zöe and Rodan, Lance and Nabbout, Rima and Barcia, Giulia and Rosenfeld, Jill A and Bacino, Carlos A and Mignot, Cyril and Power, Lillian H and Harris, Catharine J and Marjanovic, Dragan and Møller, Rikke S and Hammer, Trine B and Keski Filppula, Riikka and Vieira, Päivi and Hildebrandt, Clara and Sacharow, Stephanie and Maragliano, Luca and Benfenati, Fabio and Lachlan, Katherine and Benneche, Andreas and Petit, Florence and de Sainte Agathe, Jean Madeleine and Hallinan, Barbara and Si, Yue and Wentzensen, Ingrid M and Zou, Fanggeng and Narayanan, Vinodh and Matsumoto, Naomichi and Boncristiano, Alessandra and la Marca, Giancarlo and Kato, Mitsuhiro and Anderson, Kristin and Barba, Carmen and Sturiale, Luisa and Garozzo, Domenico and Bei, Roberto and Masuelli, Laura and Conti, Valerio and Novarino, Gaia and Fassio, Anna}, issn = {1460-2156}, journal = {Brain}, keywords = {Neurology (clinical)}, number = {8}, pages = {2687--2703}, publisher = {Oxford University Press}, title = {{Phenotypic and genetic spectrum of ATP6V1A encephalopathy: A disorder of lysosomal homeostasis}}, doi = {10.1093/brain/awac145}, volume = {145}, year = {2022}, } @article{12268, abstract = {The complexity of the microenvironment effects on cell response, show accumulating evidence that glioblastoma (GBM) migration and invasiveness are influenced by the mechanical rigidity of their surroundings. The epithelial–mesenchymal transition (EMT) is a well-recognized driving force of the invasive behavior of cancer. However, the primary mechanisms of EMT initiation and progression remain unclear. We have previously showed that certain substrate stiffness can selectively stimulate human GBM U251-MG and GL15 glioblastoma cell lines motility. The present study unifies several known EMT mediators to uncover the reason of the regulation and response to these stiffnesses. Our results revealed that changing the rigidity of the mechanical environment tuned the response of both cell lines through change in morphological features, epithelial-mesenchymal markers (E-, N-Cadherin), EGFR and ROS expressions in an interrelated manner. Specifically, a stiffer microenvironment induced a mesenchymal cell shape, a more fragmented morphology, higher intracellular cytosolic ROS expression and lower mitochondrial ROS. Finally, we observed that cells more motile showed a more depolarized mitochondrial membrane potential. Unravelling the process that regulates GBM cells’ infiltrative behavior could provide new opportunities for identification of new targets and less invasive approaches for treatment.}, author = {Basilico, Bernadette and Palamà, Ilaria Elena and D’Amone, Stefania and Lauro, Clotilde and Rosito, Maria and Grieco, Maddalena and Ratano, Patrizia and Cordella, Federica and Sanchini, Caterina and Di Angelantonio, Silvia and Ragozzino, Davide and Cascione, Mariafrancesca and Gigli, Giuseppe and Cortese, Barbara}, issn = {2234-943X}, journal = {Frontiers in Oncology}, keywords = {Cancer Research, Oncology}, publisher = {Frontiers Media}, title = {{Substrate stiffness effect on molecular crosstalk of epithelial-mesenchymal transition mediators of human glioblastoma cells}}, doi = {10.3389/fonc.2022.983507}, volume = {12}, year = {2022}, } @article{10818, abstract = {Microglia cells are active players in regulating synaptic development and plasticity in the brain. However, how they influence the normal functioning of synapses is largely unknown. In this study, we characterized the effects of pharmacological microglia depletion, achieved by administration of PLX5622, on hippocampal CA3-CA1 synapses of adult wild type mice. Following microglial depletion, we observed a reduction of spontaneous and evoked glutamatergic activity associated with a decrease of dendritic spine density. We also observed the appearance of immature synaptic features and higher levels of plasticity. Microglia depleted mice showed a deficit in the acquisition of the Novel Object Recognition task. These events were accompanied by hippocampal astrogliosis, although in the absence ofneuroinflammatory condition. PLX-induced synaptic changes were absent in Cx3cr1−/− mice, highlighting the role of CX3CL1/CX3CR1 axis in microglia control of synaptic functioning. Remarkably, microglia repopulation after PLX5622 withdrawal was associated with the recovery of hippocampal synapses and learning functions. Altogether, these data demonstrate that microglia contribute to normal synaptic functioning in the adult brain and that their removal induces reversible changes in organization and activity of glutamatergic synapses.}, author = {Basilico, Bernadette and Ferrucci, Laura and Ratano, Patrizia and Golia, Maria T. and Grimaldi, Alfonso and Rosito, Maria and Ferretti, Valentina and Reverte, Ingrid and Sanchini, Caterina and Marrone, Maria C. and Giubettini, Maria and De Turris, Valeria and Salerno, Debora and Garofalo, Stefano and St‐Pierre, Marie‐Kim and Carrier, Micael and Renzi, Massimiliano and Pagani, Francesca and Modi, Brijesh and Raspa, Marcello and Scavizzi, Ferdinando and Gross, Cornelius T. and Marinelli, Silvia and Tremblay, Marie‐Ève and Caprioli, Daniele and Maggi, Laura and Limatola, Cristina and Di Angelantonio, Silvia and Ragozzino, Davide}, issn = {1098-1136}, journal = {Glia}, keywords = {Cellular and Molecular Neuroscience, Neurology}, number = {1}, pages = {173--195}, publisher = {Wiley}, title = {{Microglia control glutamatergic synapses in the adult mouse hippocampus}}, doi = {10.1002/glia.24101}, volume = {70}, year = {2022}, } @unpublished{11943, abstract = {Complex wiring between neurons underlies the information-processing network enabling all brain functions, including cognition and memory. For understanding how the network is structured, processes information, and changes over time, comprehensive visualization of the architecture of living brain tissue with its cellular and molecular components would open up major opportunities. However, electron microscopy (EM) provides nanometre-scale resolution required for full in-silico reconstruction1–5, yet is limited to fixed specimens and static representations. Light microscopy allows live observation, with super-resolution approaches6–12 facilitating nanoscale visualization, but comprehensive 3D-reconstruction of living brain tissue has been hindered by tissue photo-burden, photobleaching, insufficient 3D-resolution, and inadequate signal-to-noise ratio (SNR). Here we demonstrate saturated reconstruction of living brain tissue. We developed an integrated imaging and analysis technology, adapting stimulated emission depletion (STED) microscopy6,13 in extracellularly labelled tissue14 for high SNR and near-isotropic resolution. Centrally, a two-stage deep-learning approach leveraged previously obtained information on sample structure to drastically reduce photo-burden and enable automated volumetric reconstruction down to single synapse level. Live reconstruction provides unbiased analysis of tissue architecture across time in relation to functional activity and targeted activation, and contextual understanding of molecular labelling. This adoptable technology will facilitate novel insights into the dynamic functional architecture of living brain tissue.}, author = {Velicky, Philipp and Miguel Villalba, Eder and Michalska, Julia M and Wei, Donglai and Lin, Zudi and Watson, Jake and Troidl, Jakob and Beyer, Johanna and Ben Simon, Yoav and Sommer, Christoph M and Jahr, Wiebke and Cenameri, Alban and Broichhagen, Johannes and Grant, Seth G. N. and Jonas, Peter M and Novarino, Gaia and Pfister, Hanspeter and Bickel, Bernd and Danzl, Johann G}, booktitle = {bioRxiv}, publisher = {Cold Spring Harbor Laboratory}, title = {{Saturated reconstruction of living brain tissue}}, doi = {10.1101/2022.03.16.484431}, year = {2022}, } @unpublished{11950, abstract = {Mapping the complex and dense arrangement of cells and their connectivity in brain tissue demands nanoscale spatial resolution imaging. Super-resolution optical microscopy excels at visualizing specific molecules and individual cells but fails to provide tissue context. Here we developed Comprehensive Analysis of Tissues across Scales (CATS), a technology to densely map brain tissue architecture from millimeter regional to nanoscopic synaptic scales in diverse chemically fixed brain preparations, including rodent and human. CATS leverages fixation-compatible extracellular labeling and advanced optical readout, in particular stimulated-emission depletion and expansion microscopy, to comprehensively delineate cellular structures. It enables 3D-reconstructing single synapses and mapping synaptic connectivity by identification and tailored analysis of putative synaptic cleft regions. Applying CATS to the hippocampal mossy fiber circuitry, we demonstrate its power to reveal the system’s molecularly informed ultrastructure across spatial scales and assess local connectivity by reconstructing and quantifying the synaptic input and output structure of identified neurons.}, author = {Michalska, Julia M and Lyudchik, Julia and Velicky, Philipp and Korinkova, Hana and Watson, Jake and Cenameri, Alban and Sommer, Christoph M and Venturino, Alessandro and Roessler, Karl and Czech, Thomas and Siegert, Sandra and Novarino, Gaia and Jonas, Peter M and Danzl, Johann G}, booktitle = {bioRxiv}, publisher = {Cold Spring Harbor Laboratory}, title = {{Uncovering brain tissue architecture across scales with super-resolution light microscopy}}, doi = {10.1101/2022.08.17.504272}, year = {2022}, }