TLR are crucially important in the detection of infectious agents. To date, 11 receptors have been discovered. Each receptor
recognizes distinct antigens and triggers a specific cascade of transcription factors; however, all TLR use the NF-κB transcription factor 21. In addition, non-TLR signaling of zymosan by Dectin-1 is synergistic and activates NF-κB, even in the absence of TLR 22. In fact, NF-κB is a major transcription factor that has been implicated as a critical regulator of gene expression in the setting of inflammation in general, and particularly in IL-1β and IL-6 secretion 23, 24. In cytoplasm, NF-κB exists in an inactive form associated with proteins that are known IkB. Extracellular stimuli activate two IkB kinases, which phosphorylate IkB, which is then selectively
ubiquitinated and degraded by the 26S proteasome 25, 26. NF-κB activation is achieved through the signal-induced RG7204 datasheet proteolytic degradation of IkB in cytoplasm, allowing NF-κB to interact with nuclear import machinery and translocate to the nucleus, where it binds to target genes to initiate transcription. As demonstrated ABT-263 mw in Fig. 5A, non-opsonic zymosan activates NF-κB. However, upon interaction with iC3b-opsonized apoptotic cells, and despite marked inhibition of IL-1β and IL-6 secretion, we were able to document only partial inhibition of phosphorylated degraded IkB in both macrophages and DC (five experiments, Fig. 5A). Molecular motor Therefore, we used another system based on flow cytometry and fluorescent microscopy to verify NF-κB inhibition. As shown in Fig. 5A and B, migration of cytoplasmic p65 is triggered by both LPS and zymosan, resulting in downregulation of cytoplasmic p65 staining (p<0.001, Kolmogorov−Smirnov analysis). Adding apoptotic cells was clearly associated with decreased inhibition (p<0.001, Kolmogorov−Smirnov analysis), as shown in Fig. 5B and C. This was also demonstrated by fluorescent microscopy, which
showed inhibition of nuclear p65 translocalization (Fig. 5C). Bright staining is shown following zymosan uptake, but only mild staining occurred when macrophages were exposed to iC3b-opsonized apoptotic cells prior to zymosan exposure. Next we wanted to verify whether NF-κB inhibition is expressed downstream. We established a luciferase reporter gene with human NF-κB promoter upstream to the luciferase reporter gene that was introduced into iDC, which were then incubated with zymosan in the presence or absence of iC3b-opsonized apoptotic cells. As shown in Fig. 5D, NF-κB inhibition was clearly demonstrated in the presence of iC3b-opsonized apoptotic cells (p<0.01). This was repeated with iC3b-opsonized apoptotic splenocytes in order to exclude a thymocyte-specific effect, with similar results (data not shown).