Previous studies identified IQGAP1 as a component of the actin cy

Previous studies identified IQGAP1 as a component of the actin cytoskeleton of NK cells 12. Subsequently, Stinchcombe et al. described the presence of IQGAP1 in the IS of CTLs 10. Our results indicate that IQGAP1 displays similar dynamic spatial and temporal changes in NK cells during conjugate formation and granule delivery. Although there did not appear to be any significant increase in the levels

of IQGAP1 at the NKIS, there were dramatic changes during the terminal stages of Wnt pathway synapse maturation. As the granules approached the NKIS, both the IQGAP1 and the filamentous actin were cleared from the regions of granule delivery. This could provide cytolytic granules the direct access to the effector cell plasma membrane which is necessary for the release of granule contents at the NKIS. Although the loss of IQGAP1 nearly completely inhibited cytotoxicity, the proportion of silenced cells forming conjugates was significantly increased relative to control cells, suggesting that the initial adhesion steps were not IQGAP1 dependent. In contrast, the capacity to reorient the MTOC to form a mature

synapse was markedly inhibited, implying signaling pathway that IQGAP1 was required for this process. IQGAP1 can selectively bind to Cdc42 to maintain it in a GTP bound activated form. Stinchcombe et al. proposed that IQGAP1 interaction with Cdc42 facilitates the attachment of microtubules to F-actin at the IS 10. This redistribution of IQGAP1 from the IS would result in the partitioning of actin causing reorganization of microtubules. Consistent with this proposed mechanism, we observed that IQGAP1 in YTS and pNK cells partitions from the IS prior to degranulation. Our preliminary observations suggest that IQGAP1 partitioning in the mature synapse immediately precedes that of actin. The close

proximity of a component of the IQGAP1 pool and an F-actin network with the perforin-containing granules suggests that IQGAP1 may play a role in granule organization in NK cells. This was implied by the fact that the granules in ∼20% of the silenced cells were diffusely distributed throughout the cells. This pattern appeared in those cells with the highest degree of IQGAP1 silencing. In these circumstances, there was a complete loss of of the perigranular F-actin network, suggesting a possible role for the latter in granule organization. Those cells with incomplete silencing of IQGAP1 expression showed convergence of granules toward the MTOC with incomplete reorientation to the NKIS. We suggest that IQGAP1 may facilitate the formation or stabilization of F-actin bundles in the perigranular region, which could provide a structural framework that confines the granule distribution. F-actin coating of secretory granules and its role in exocytosis has been previously demonstrated in pancreatic acinar cells 34, 35 and platelets 36.

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