Abstract.To study the effector function of the ADPribosylation factor (ARF) 6 GTP-binding protein, we transfected HeLa cells with wild-type, epitope-tagged ARF6. Previously shown to indirectly activate the ARF1 GTPase, aluminum fluoride (AIF) treatment of ARF6-transfected cells resulted in a redistribution of both ARF6 and actin to discrete sites on the plasma membrane, which became increasingly protrusive over time. The effects of A1F were reversible, specific to cells transfected with wild-type ARF6, and resembled the cellular protrusions observed in cells expressing the GTPase defective mutant of ARF6. Importantly, the protrusions observed in cells transfected with ARF6were distinct from the enhanced stress fibers and membrane ruffles observed in cells transfected with RhoA and Racl, respectively. In cells forming protrusions, there was an apparent stimulation of macropinocytosis and membrane recycling within the protrusive structures. In contrast, no block in transferrin uptake or alteration of the distribution of clathrin AP-2 complexes was detected in these cells. The AIF-induced, ARF6-dependent formation of protrusive structures was blocked by cytochalasin D and inhibitors of the lipoxygenase pathway. These observations support a novel role for the ARF6 GTPase in modeling the plasma membrane and underlying cytoskeleton.T HE actin cytoskeleton is a dynamic, structural component of cells that plays a key role in determining cell shape, motility, and cytokinesis. The assembly of actin filaments in cells is regulated tightly and, depending upon the association with numerous proteins, results in a distinctive cellular morphology (Bretscher, 1991;Condeelis, 1993;Stossel, 1993). Two major types of actin arrangements are found in most mammalian cells. Actin stress fibers are composed of contractile bundles of actin filaments, extending across the cell and anchored to the plasma membrane at focal adhesions. Additionally, a mesh of cortical actin filaments is responsible, through assembly and disassembly, for forming the transient ruffles and protrusions of cells (Harris, 1989). Changes in cortical actin can be initiated through various signal transduction pathways and, as a consequence, result in increased cell motility and chemotaxis
