Browsing by Author "Amador, Cristian A."

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    A preclinical mice model of multiple sclerosis based on the toxin-induced double-site demyelination of callosal and cerebellar fibers
    (2024) Vejar, Sebastián; Pizarro, Ignacio S.; Pulgar-Sepúlveda, Raúl; Vicencio, Sinay C.; Polit, Andrés; Amador, Cristian A.; Rio, Rodrigo del; Varas, Rodrigo; Orellana, Juan A.; Ortiz, Fernando C.
    Background: Multiple sclerosis (MS) is an irreversible progressive CNS pathology characterized by the loss of myelin (i.e. demyelination). The lack of myelin is followed by a progressive neurodegeneration triggering symptoms as diverse as fatigue, motor, locomotor and sensory impairments and/or bladder, cardiac and respiratory dysfunction. Even though there are more than fourteen approved treatments for reducing MS progression, there are still no cure for the disease. Thus, MS research is a very active field and therefore we count with different experimental animal models for studying mechanisms of demyelination and myelin repair, however, we still lack a preclinical MS model assembling demyelination mechanisms with relevant clinical-like signs. Results: Here, by inducing the simultaneous demyelination of both callosal and cerebellar white matter fibers by the double-site injection of lysolecithin (LPC), we were able to reproduce CNS demyelination, astrocyte recruitment and increases levels of proinflammatory cytokines levels along with motor, locomotor and urinary impairment, as well as cardiac and respiratory dysfunction, in the same animal model. Single site LPC-injections either in corpus callosum or cerebellum only, fails in to reproduce such a complete range of MS-like signs. Conclusion: We here report that the double-site LPC injections treatment evoke a complex MS-like mice model. We hope that this experimental approach will help to deepen our knowledge about the mechanisms of demyelinated diseases such as MS.
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    Aldosterone Promotes Autoimmune Damage by Enhancing Th17-Mediated Immunity
    (AMER ASSOC IMMUNOLOGISTS, 2010) Herrada, Andres A.; Contreras, Francisco J.; Marini, Natacha P.; Amador, Cristian A.; Gonzalez, Pablo A.; Cortes, Claudia M.; Riedel, Claudia A.; Carvajal, Cristian A.; Figueroa, Fernando; Michea, Luis F.; Fardella, Carlos E.; Kalergis, Alexis M.
    Excessive production of aldosterone leads to the development of hypertension and cardiovascular disease by generating an inflammatory state that can be promoted by T cell immunity. Because nature and intensity of T cell responses is controlled by dendritic cells (DCs), it is important to evaluate whether the function of these cells can be modulated by aldosterone. In this study we show that aldosterone augmented the activation of CD8(+) T cells in a DC-dependent fashion. Consistently, the mineralocorticoid receptor was expressed by DCs, which showed activation of MAPK pathway and secreted IL-6 and TGF-beta in response to aldosterone. In addition, DCs stimulated with aldosterone impose a Th17 phenotype to CD4(+) T cells, which have recently been associated with the promotion of inflammatory and autoimmune diseases. Accordingly, we observed that aldosterone enhances the progression of experimental autoimmune encephalomyelitis, an autoimmune disease promoted by Th17 cells. In addition, blockade of the mineralocorticoid receptor prevented all aldosterone effects on DCs and attenuated experimental autoimmune encephalomyelitis development in aldosterone-treated mice. Our data suggest that modulation of DC function by aldosterone enhances CD8(+) T cell activation and promotes Th17-polarized immune responses, which might contribute to the inflammatory damage leading to hypertension and cardiovascular disease. The Journal of Immunology, 2010, 184: 191-202.
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    Endogenous Galectin-8 protects against Th17 infiltration and fibrosis following acute kidney injury
    (Springer Nature, 2025) Perez-Moreno, Elisa; Peña, Adely de la; Toledo, Tomás; Saez, Javiera; Pérez-Molina, Francisca; Espinoza, Sofía; Metz, Claudia; Díaz-Valdivia, Nicole; Azócar, Lorena; Prado, Carolina; Pacheco, Rodrigo; Segovia-Miranda, Fabian; Godoy, Alejandro S.; Amador, Cristian A.; Feuerhake González, Teo; González, Alfonso; Soza, Andrea
    Background Acute kidney injury (AKI) is a serious clinical condition characterized by a rapid decline in renal function, often progressing to chronic kidney disease (CKD) and fibrosis. The endogenous mechanisms influencing kidney injury resolution or maladaptive repair remain poorly understood. Galectin‑8 (Gal‑8), a tandem‑repeat β‑galactosidebinding lectin, plays a role in epithelial cell proliferation, epithelial‑mesenchymal transition, and immune regulation, all of which are critical in AKI outcomes. While exogenous Gal‑8 administration has shown renoprotective effects, its endogenous role in kidney injury progression and resolution remains unclear. Methods To investigate the endogenous role of Gal‑8 in AKI, we compared the responses of Gal‑8 knockout (Gal8‑KO; Lgals8−/− bearing a β‑gal cassette under the Lgals8 gene promoter) and wild‑type (Lgals8+/+) mice in a nephrotoxic folic acid (FA)‑induced AKI model. Renal Gal‑8 expression was assessed by β‑galactosidase staining, lectin‑marker colocalization, and RT‑qPCR. Renal function, structure, and immune responses were evaluated at the acute (day 2) and fibrotic (day 14) phases of injury. Plasma creatinine levels were measured to assess renal function, while histological analyses evaluated tubular damage, renal inflammation, and extracellular matrix deposition. Flow cytometry was performed to characterize the immune response, focusing on pro‑inflammatory T cells. Results Galectin‑8 was predominantly expressed in the renal cortex, localizing to tubules, glomeruli, and blood vessels, with its levels decreasing by half following AKI. Both Lgals8+/+ and Lgals8−/− mice exhibited similar renal function and structure impairments during the acute phase, though Lgals8+/+ mice showed slightly worse damage. By the fibrotic phase, Lgals8−/− mice exhibited more pronounced cortical damage and fibrosis, characterized by increased type I and III collagen deposition and enhanced Th17 cell infiltration, while myofibroblast activation remained comparable to that of Lgals8+/+ mice. Conclusions Endogenous Gal‑8 does not significantly protect the kidney during the acute phase and is dispensable for cell proliferation and death in response to AKI. However, it is crucial in preventing maladaptive repair by regulating.