Browsing by Author "Woehlbier, Ute"
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Item ALS-linked protein disulfide isomerase variants cause motor dysfunction(European Molecular Biology Organization by IRL Press, 2016) Woehlbier, Ute; Colombo, Alicia; Saaranen, Mirva; Pérez, Viviana; Ojeda, Jorge; Bustos, Fernando; Andreu, Catherine; Torres, mauricio; Valenzuela, Vicente; Medinas, Danilo; Rozas, Pablo; Vidal, René; López-González, Rodrigo; Salameh, Johnny; Fernández-Collemann, Sara; Muñoz, Natalia; Matus, Soledad; Armisén, Ricardo; Sagredo, Alfredo; Palma, Karina; Irrazabal, Thergiory; Almeida, Sandra; González-Pérez, Paloma; Campero, MarioDisturbance of endoplasmic reticulum (ER) proteostasis is a common feature of amyotrophic lateral sclerosis (ALS). Protein disulfide isomerases (PDIs) areERfoldases identified as possibleALSbiomarkers, as well as neuroprotective factors. However, no functional studies have addressed their impact on the disease process. Here, we functionally characterized fourALS-linked mutations recently identified in two majorPDIgenes,PDIA1 andPDIA3/ERp57. Phenotypic screening in zebrafish revealed that the expression of thesePDIvariants induce motor defects associated with a disruption of motoneuron connectivity. Similarly, the expression of mutantPDIs impaired dendritic outgrowth in motoneuron cell culture models. Cellular and biochemical studies identified distinct molecular defects underlying the pathogenicity of thesePDImutants. Finally, targetingERp57 in the nervous system led to severe motor dysfunction in mice associated with a loss of neuromuscular synapses. This study identifiesERproteostasis imbalance as a risk factor forALS, driving initial stages of the disease.Item Neuronal Rubicon Represses Extracellular APP/Amyloid β Deposition in Alzheimer’s Disease(2022) Espinoza, Sandra; Grunenwald, Felipe; Gomez, Wileidy; García, Felipe; Abarzúa, Lorena; Oyarce, Sebastián; Hernández, María; Cortés, Bastián; Uhrig, Markus; Ponce, Daniela; Durán, Claudia; Hetz, Claudio; SanMartín, Carol; Cornejo, Victor; Ezquer, Fernando; Parra, Valentina; Behrens, María; Manque, Patricio; Rojas, Diego; Vidal, René; Woehlbier, Ute; Nassif, MelissaAlzheimer’s disease (AD) is the most prevalent age-associated neurodegenerative disease. A decrease in autophagy during aging contributes to brain disorders by accumulating potentially toxic substrates in neurons. Rubicon is a well-established inhibitor of autophagy in all cells. However, Rubicon participates in different pathways depending on cell type, and little information is currently available on neuronal Rubicon’s role in the AD context. Here, we investigated the cell-specific expression of Rubicon in postmortem brain samples from AD patients and 5xFAD mice and its impact on amyloid β burden in vivo and neuroblastoma cells. Further, we assessed Rubicon levels in human-induced pluripotent stem cells (hiPSCs), derived from early-to-moderate AD and in postmortem samples from severe AD patients. We found increased Rubicon levels in AD-hiPSCs and postmortem samples and a notable Rubicon localization in neurons. In AD transgenic mice lacking Rubicon, we observed intensified amyloid β burden in the hippocampus and decreased Pacer and p62 levels. In APP-expressing neuroblastoma cells, increased APP/amyloid β secretion in the medium was found when Rubicon was absent, which was not observed in cells depleted of Atg5, essential for autophagy, or Rab27a, required for exosome secretion. Our results propose an uncharacterized role of Rubicon on APP/amyloid β homeostasis, in which neuronal Rubicon is a repressor of APP/amyloid β secretion, defining a new way to target AD and other similar diseases therapeuticallyPublication The Autophagy Protein Pacer Positively Regulates the Therapeutic Potential of Mesenchymal Stem Cells in a Mouse Model of DSS-Induced Colitis(2022) Bergmann, Cristian; Beltran, Sebastian; Vega, Ana; Murgas, Paola; Hernández, Maria; Gómez, Laura; Labrador, Luis; Cortés, Bastián; Poblete, Cristian; Quijada, Cristobal; Carrión, Flavio; Woehlbier, Ute; Manque, PatricioMesenchymal stem cells (MSC) have emerged as a promising tool to treat inflammatory diseases, such as inflammatory bowel disease (IBD), due to their immunoregulatory properties. Frequently, IBD is modeled in mice by using dextran sulfate sodium (DSS)-induced colitis. Recently, the modulation of autophagy in MSC has been suggested as a novel strategy to improve MSC-based immunotherapy. Hence, we investigated a possible role of Pacer, a novel autophagy enhancer, in regulating the immunosuppressive function of MSC in the context of DSS-induced colitis. We found that Pacer is upregulated upon stimulation with the pro-inflammatory cytokine TNFα, the main cytokine released in the inflammatory environment of IBD. By modulating Pacer expression in MSC, we found that Pacer plays an important role in regulating the autophagy pathway in this cell type in response to TNFα stimulation, as well as in regulating the immunosuppressive ability of MSC toward T-cell proliferation. Furthermore, increased expression of Pacer in MSC enhanced their ability to ameliorate the symptoms of DSS-induced colitis in mice. Our results support previous findings that autophagy regulates the therapeutic potential of MSC and suggest that the augmentation of autophagic capacity in MSC by increasing Pacer levels may have therapeutic implications for IBD.