First, data from the OT1 system using recombinant TCR, where no t

First, data from the OT1 system using recombinant TCR, where no triggering is present, shows that 2D off-rate for agonist is even faster than that of native TCR on the cell surface (Liu, B. et al., our unpublished data). Second, all the TCRs in the current study showed fast kinetics, reaching adhesion plateau from the shortest contact time of 0.1 s. The fact that the adhesion did not increase further in longer contact times suggests that factors contributing to the adhesion did not change significantly over the time scale of our 2D measurement. Thus, should signaling have occurred, it was within 0.1 s, which, to the best of

GSI-IX order our knowledge, is faster than any documented T-cell

signaling events. Third, in our 2D assays, off-rate measurement was performed at zero-force condition. As we elaborated previously [27, 37], in the adhesion frequency assay, the stretch at the end of each contact is merely a means of detecting whether a bond was present at the very end of the contact; the binary readout (bond or no bond) but not bond duration are analyzed PLX3397 in vitro with a mathematical model to derive the off-rate. In the thermal fluctuation assay, more direct evidence is available for the zero-force condition because we quantitatively monitor the force (by tracking the position of the biomembrane force probe (BFP) probe bead). If any cellular processes impose forces significantly deviate from zero on individual TCR–pMHC bonds, we should have observed them (the BFP has a ∼1 pN force resolution). Fourth, the surface density of pMHC http://www.selleck.co.jp/products/CHIR-99021.html is carefully controlled such that, at any moment of contact, the majority of adhesion events are mediated by a single bond [37]. Therefore, although we cannot rule out a possible

role of T-cell signaling, these factors would favor the proposition that 2D TCR–pMHC off-rate most likely reflects an intrinsic property of the native TCR in the cell membrane. One intriguing property of 2D off-rate (or bond lifetime) for the gp100 system is that higher potency corresponds to a faster off-rate (thus shorter bond lifetime), which was also observed in the OT1 [27], 42F3 [33], and 2B4 and 5C.C7 [28] TCR systems. However, higher potency interactions have much higher on-rates. Evaluation based on both on-rates and off-rates is actually consistent with the serial engagement model [27] and the total confinement time model [42]. Take 19LF6 TCR as an example. The measured on-rate (Ackon) is 0.072 μm4s−1 and off-rate (koff) is 11.4/s. For typical surface densities of 15 TCR/μm2 (mTCR) and 6 pMHC/μm2 (mpMHC) on a T cell and an RBC, respectively, it takes on average 0.15 s (1/(Ackon×mTCR×mpMHC)) for a new TCR–pMHC bond to form and 0.088 s (1/koff) to dissociate.

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