Toyooka Lab

Translational Research for Autism & Parkinson's Disease

CD28 co-stimulatory signals induce IL-2 receptor expression on antigen-stimulated virgin T cells by an IL-2-independent mechanism.


Journal article


K. Toyooka, S. Maruo, T. Iwahori, N. Yamamoto, X. Tai, R. Abe, Y. Takahama, M. Murakami, T. Uede, T. Hamaoka, H. Fujiwara
International immunology, 1996

Semantic Scholar DOI PubMed
Cite

Cite

APA   Click to copy
Toyooka, K., Maruo, S., Iwahori, T., Yamamoto, N., Tai, X., Abe, R., … Fujiwara, H. (1996). CD28 co-stimulatory signals induce IL-2 receptor expression on antigen-stimulated virgin T cells by an IL-2-independent mechanism. International Immunology.


Chicago/Turabian   Click to copy
Toyooka, K., S. Maruo, T. Iwahori, N. Yamamoto, X. Tai, R. Abe, Y. Takahama, et al. “CD28 Co-Stimulatory Signals Induce IL-2 Receptor Expression on Antigen-Stimulated Virgin T Cells by an IL-2-Independent Mechanism.” International immunology (1996).


MLA   Click to copy
Toyooka, K., et al. “CD28 Co-Stimulatory Signals Induce IL-2 Receptor Expression on Antigen-Stimulated Virgin T Cells by an IL-2-Independent Mechanism.” International Immunology, 1996.


BibTeX   Click to copy

@article{k1996a,
  title = {CD28 co-stimulatory signals induce IL-2 receptor expression on antigen-stimulated virgin T cells by an IL-2-independent mechanism.},
  year = {1996},
  journal = {International immunology},
  author = {Toyooka, K. and Maruo, S. and Iwahori, T. and Yamamoto, N. and Tai, X. and Abe, R. and Takahama, Y. and Murakami, M. and Uede, T. and Hamaoka, T. and Fujiwara, H.}
}

Abstract

Intravenous sensitization of C57BL/6 (B6) mice with class II H-2-disparate B6-C-H-2bm12(bm12) resting B cells induced anti-bm12 CD4+ T cell tolerance as shown by hyporesponsiveness in the anti-bm12 mixed lymphocyte reaction (MLR). The present study investigated the mechanism(s) of the failure of bm12 B cells to stimulate the proliferation of B6 anti-bm12 CD4+ T cells. While stimulation in vitro to B6 splenic T cells with bm12 antigen-presenting cells (APC) induced IL-2 mRNA expression and IL-2 production, T cells stimulated with bm12 B cells expressed much less IL-2 mRNA and secreted very low but detectable levels of IL-2. Moreover, the T cells stimulated with the bm12 B cells did not proliferate and this was not corrected by the addition of rIL-2 responsiveness. Further, whereas IL-2 receptor (IL-2R) alpha chain expression was significantly induced on B6 T cells stimulated with bm12 APC; stimulation with bm12 B cells did not induce IL-2R expression over background levels. However, virgin T cells stimulated with both bm12 B cells and anti-CD28 mAb proliferated and displayed a dramatic increase in IL-2 production as well as IL-2R expression to levels commensurate with those resulting from bm12 B cells plus anti-CD28 mAb even in the presence of sufficient amounts of anti-IL-2 mAb for neutralizing produced IL-2; while levels of IL-2R were significantly lower compared to those induced in the absence of anti-IL-2 mAb, increased frequencies of IL-2R+ cells were comparable. Conversely, IL-2R was not induced by bm12 B cell stimulation in the presence of IL-2. Moreover, IL-2R expression and proliferation induced by stimulation with bm12 APC was inhibited by CTLA-4-Ig, a soluble recombinant fusion protein capable of blocking the CD28 co-stimulatory signals not only stimulate IL-2 production but also induce IL-2R expression by an IL-2-independent mechanism.