To verify these results we performed an acceptor photobleaching FRET assay. Our results indicate that the trend observed in the donor-sensitized acceptor fluorescence emission FRET analysis was maintained since a significantly find more higher relative FRET efficiency was observed in cells expressing WT ζ WT versus MUT ζ MUT(Supporting Information Fig. 4C). To assess whether ζ has a structural effect on actin reorganization, we hypothesized that the positively charged ζ motifs could be involved in actin bundling, as observed for various proteins containing positively charged clusters [15, 16]. To

this end, F-actin was mixed with different concentrations of WT or MUT IC ζ proteins, stained and analyzed by

electron microscopy. As shown in Fig. 1F, while actin filaments incubated alone appear individually dispersed and disorganized in the field, addition of the WT mouse (mWT ICζ) or human (hWT ICζ) proteins induced actin organization and formation of bundles that appear as wide branches (lower middle panel) similar to those induced by the positively charged poly-l-lysine. In contrast, when the MUT ICζ was added, a disorganized actin microfilament field is observed. These results indicate that the two ζ chain RRR motifs of the mouse and human origin mediate not only the direct association with actin but also induce bundling of actin filaments. We next analyzed whether the ζ basic motifs are also responsible for its association with the cytoskeleton within T cells. To this end, we stably expressed the full RXDX-106 research buy length (WT) or the double mutated (MUT) ζ in ζ−deficient hybridoma T cells, which lack TCR cell surface expression.

Both WT and MUT ζ−expressing cells restored TCR surface expression (Supporting Information Fig. 5A), suggesting a normal association between the WT and MUT ζ and the remaining TCR subunits. Moreover, immunoprecipitation of ζ from WT and MUT cells using anti-ζ Abs (“a”–“d”), directed against different epitopes within the ζ IC region, depicted similar ζ levels precipitated from both cell types (Supporting Information Fig. 5B and C). These indicate that the ζ mutations did not affect its conformation. In all comparative experiments WT and MUT expressing Thalidomide cells expressed similar cell surface TCR levels. To assess the effect of ζ mutations on its association with the cytoskeleton, we compared the distribution of the cska- and non-cska-TCR forms between the two cell types. Total non-cska ζ levels in both WT- and MUT-expressing cells were similar to those of the parental ζ−expressing 2B4 cells from which the ζ-deficient T cells were derived (Fig. 2A). However, mutations in the basic motifs disrupted the ζ cytoskeleton association, resulting in a pronounced impairment of the cska-TCRs, with only a negligible expression (Fig. 2A).