Ren, H.; Lee, H.-R.; Omar, Y. A. D.; DeGrandchamp, J. B.; Hung, C.-L.; Eisen, T. J.; Stamou, D.; Kuriyan, J.; Chakraborty, A. K.; Groves, J. T.

T cells can respond to even a single molecular binding event of antigen to a TCR. A key step in the TCR signaling pathway that definitively exhibits this single molecule response is the initiation of calcium influx by activation of PLC{gamma}1 in the LAT protein condensate. Here, we describe detailed kinetic measurements examining how protein condensation of LAT regulates activation of PLC{gamma}1 using a reconstituted membrane system. The results reveal that membrane recruitment of PLC{gamma}1 is tightly controlled by the LAT phosphorylation state, with no measurable independent recruitment to PIP2 or PIP3 lipids via the PLC{gamma}1 PH domains. We further observe PLC{gamma}1 is rapidly activated by membrane-associated kinase upon recruitment, irrespective of the LAT condensation state. These studies also revealed a crosstalk mechanism in which the TEC family kinases responsible for PLC{gamma}1 activation also phosphorylate LAT. This interaction establishes a positive feedback loop in LAT phosphorylation, mediated through LAT condensation, which drives a bimodal LAT phosphorylation response to TCR activation. Kinetic modeling reveals how this LAT phosphorylation response can cooperatively gate PLC{gamma}1 activation from a single TCR. These results suggest the LAT condensate facilitates both signal amplification and noise suppression in PLC{gamma}1 activation through a bimodal switch affecting LAT phosphorylation.