Temporalmente, el archivo digital asociado a esta publicación, no se encuentra disponible. Para más información escribir a [email protected]
Este documento se encuentra disponible en su fuente de origen, si desea acceder al texto completo, puedes hacerlo a continuación:
Autor(es)
Prado, Carolina; Osorio-Barrios, Francisco; Falcón, Paulina; Espinoza, Alexandra; Saez, Juan José; Yuseff, María Isabel; Pacheco, Rodrigo |
ISSN:
1742-2094 |
Idioma:
eng |
Fecha:
2021-12 |
Tipo:
Artículo |
Revista:
Journal of Neuroinflammation |
Datos de la publicación:
vol. 18 Issue: no. 1 Pages: |
DOI:
10.1186/s12974-021-02338-1 |
Descripción:
Publisher Copyright: © 2021, The Author(s). |
Resumen:
Background: Recent evidence has shown dopamine as a major regulator of inflammation. Accordingly, dopaminergic regulation of immune cells plays an important role in the physiopathology of inflammatory disorders. Multiple sclerosis (MS) is an inflammatory disease involving a CD4+ T-cell-driven autoimmune response to central nervous system (CNS) derived antigens. Evidence from animal models has suggested that B cells play a fundamental role as antigen-presenting cells (APC) re-stimulating CD4+ T cells in the CNS as well as regulating T-cell response by mean of inflammatory or anti-inflammatory cytokines. Here, we addressed the role of the dopamine receptor D3 (DRD3), which displays the highest affinity for dopamine, in B cells in animal models of MS. Methods: Mice harbouring Drd3-deficient or Drd3-sufficient B cells were generated by bone marrow transplantation into recipient mice devoid of B cells. In these mice, we compared the development of experimental autoimmune encephalomyelitis (EAE) induced by immunization with a myelin oligodendrocyte glycoprotein (MOG)-derived peptide (pMOG), a model that leads to CNS-autoimmunity irrespective of the APC-function of B cells, or by immunization with full-length human MOG protein (huMOG), a model in which antigen-specific activated B cells display a fundamental APC-function in the CNS. APC-function was assessed in vitro by pulsing B cells with huMOG-coated beads and then co-culturing with MOG-specific T cells. Results: Our data show that the selective Drd3 deficiency in B cells abolishes the disease development in the huMOG-induced EAE model. Mechanistic analysis indicates that although DRD3-signalling did not affect the APC-function of B cells, DRD3 favours the CNS-tropism in a subset of pro-inflammatory B cells in the huMOG-induced EAE model, an effect that was associated with higher CXCR3 expression. Conversely, the results show that the selective Drd3 deficiency in B cells exacerbates the disease severity in the pMOG-induced EAE model. Further analysis shows that DRD3-stimulation increased the expression of the CNS-homing molecule CD49d in a B-cell subset with anti-inflammatory features, thus attenuating EAE manifestation in the pMOG-induced EAE model. Conclusions: Our findings demonstrate that DRD3 in B cells exerts a dual role in CNS-autoimmunity, favouring CNS-tropism of pro-inflammatory B cells with APC-function and promoting CNS-homing of B cells with anti-inflammatory features. Thus, these results show DRD3-signalling in B cells as a critical regulator of CNS-autoimmunity. |
Ficheros | Tamaño | Formato | Ver |
---|---|---|---|
No hay ficheros asociados a este ítem. |
El Repositorio Institucional de la Universidad San Sebastián reúne los trabajos académicos y de investigación elaborados por la comunidad universitaria. Contribuye a la visibilidad y difusión, para ser consultados a través de acceso abierto por toda la comunidad nacional e internacional.
El objetivo del Repositorio es almacenar, conservar y entregar en formato electrónico, los resultados del quehacer institucional, permitiendo mayor visibilidad y difusión por medio del acceso abierto y gratuito.