Abstract
ABSTRACTTo establish intracellular infections, Salmonella bacteria trigger host cell membrane ruffling and invasion by subverting cellular Arf guanine nucleotide exchange factors (GEFs) that activate Arf1 and Arf6 GTPases by promoting GTP binding. A family of cellular Arf GTPase-activating proteins (GAPs) can downregulate Arf signaling by stimulating GTP hydrolysis, but whether they do this during infection is unknown. Here, we uncovered a remarkable role for distinct Arf GAP family members in Salmonella invasion. The Arf6 GAPs ACAP1 and ADAP1 and the Arf1 GAP ASAP1 localized at Salmonella-induced ruffles, which was not the case for the plasma membrane-localized Arf6 GAPs ARAP3 and GIT1 or the Golgi-associated Arf1 GAP1. Surprisingly, we found that loss of ACAP1, ADAP1, or ASAP1 impaired Salmonella invasion, revealing that GAPs cannot be considered mere terminators of cytoskeleton remodeling. Salmonella invasion was restored in Arf GAP-depleted cells by expressing fast-cycling Arf derivatives, demonstrating that Arf GTP/GDP cycles facilitate Salmonella invasion. Consistent with this view, both constitutively active and dominant-negative Arf derivatives that cannot undergo GTP/GDP cycles inhibited invasion. Furthermore, we demonstrated that Arf GEFs and GAPs colocalize at invading Salmonella and collaborate to drive Arf1-dependent pathogen invasion. This study revealed that Salmonella bacteria exploit a remarkable interplay between Arf GEFs and GAPs to direct cycles of Arf GTPase activation and inactivation. These cycles drive Salmonella cytoskeleton remodeling and enable intracellular infections.
Highlights
Salmonella enterica is an intracellular bacterial pathogen of worldwide importance causing diseases in animals and humans ranging from acute gastroenteritis to a systemic infection known as typhoid fever [1]
Immunofluorescence showed that endogenous ACAP1, ADAP1, and ASAP1 localized to Salmonella invasion sites
ACAP1, ADAP1, and ASAP1 localized with intracellular Salmonella were not observed as confirmed by imaging of Rab5, which is known to colocalize with Salmonella-containing vacuoles (SCVs) following pathogen uptake [20]
Summary
Salmonella enterica is an intracellular bacterial pathogen of worldwide importance causing diseases in animals and humans ranging from acute gastroenteritis to a systemic infection known as typhoid fever [1]. Salmonella bacteria invade nonphagocytic intestinal epithelial cells through the action of injected virulence effector proteins that induce cytoskeleton remodeling and membrane ruffling to trigger pathogen macropinocytosis. Salmonella-induced membrane ruffling requires actin polymerization directed by a cellular machine known as the wave regulatory complex (WRC) [2,3,4]. Salmonella bacteria encode no known Arf GEF or GAP, so, to mediate WRCdriven uptake, the pathogen must subvert the cellular network of Arf regulatory proteins. Arf is best known for its activities in membrane trafficking at the Golgi membrane, but it is recruited to the plasma membrane by its GEF Arf nucleotide-binding-site opener (ARNO), which activates Arf to induce macropinosome formation [3, 11, 12].
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