Survival or destruction of a pathogen following phagocytosis depends, in part, on fusion events between the phagosome and the endosomal or lysosomal compartments. Here we use an in vitro assay to show that phagosome-endosome fusion is regulated by the small GTPase rab5 and that fusion events are influenced by an internalized live organism, Listeria monocytogenes (LM). We compare the in vitro fusion of phagosomes containing heat-killed organisms (dead LM) with that of phagosomes containing a live nonhemolytic mutant (live LMhly-). Unlike the wild-type organism, LMhly- remains trapped inside the phagosome. Phagosome-endosome fusion was reconstituted using biotinylated organisms and endosomes containing horseradish peroxidase conjugated with avidin. With both live LMhly- and dead LM preparations, in vitro phagosome-endosome fusion was time-, temperature-, and cytosol-dependent. Live LMhly- phagosomes exhibited a faster rate of fusion. Fusion in both preparations was regulated by rab5 and possibly by other GTPases. Anti-rab5 antibodies and immunodepletion of cytosolic rab5 inhibited fusion. Addition of glutatione S-transferase-rab5 in the GTP form stimulated phagosome-endosome fusion, whereas addition of a dominant negative mutant of rab5 blocked fusion. Purified live LMhly- phagosomal membranes were enriched in rab5 as revealed by Western blotting, compared with dead LM phagosomes. Fusion of endosomes with dead LM containing phagosomes required ATP and was inhibited by ATP depletion and by N-ethylmaleimide (NEM) and anti-NEM-sensitive factor (NSF) antibodies. Unexpectedly, phagosome-endosome fusion with live LMhly--containing phagosomes was not inhibited by ATP depletion nor by NEM or anti-NSF antibodies. Western blot analysis revealed that live LMhly--containing phagosomes were enriched for membrane-bound NSF, while dead LM containing phagosomes contained low or undetectable quantities. Washing live LMhly--containing phagosomes with 0.5 M KCl removed NSF associated with the membranes and rendered them NEM, ATP, anti-NSF antibody sensitive for fusion. We conclude that rab5 regulates phagosome-endosome fusion and that live microorganisms can up-regulate this process by recruiting rab5 to the membrane.
To explore the role of GTPases in endocytosis, we developed an assay using Xenopus oocytes injected with recombinant proteins to follow the uptake of the fluid phase marker HRP. HRP uptake was inhibited in cells injected with GTPγS or incubated with aluminum fluoride, suggesting a general role for GTPases in endocytosis. Injection of Rab5 into oocytes, as well as Rab5:Q79L, a mutant with decreased GTPase activity, increased HRP uptake. Injection of Rab5:S34N, the dominant-negative mutant, inhibited HRP uptake. Injection of N-ethylmaleimide–sensitive factor (NSF) stimulated HRP uptake, and ATPase-defective NSF mutants inhibited HRP uptake when coinjected with Rab5:Q79L, confirming a requirement for NSF in endocytosis. Surprisingly, injection of Rab7:WT stimulated both uptake and degradation/activation of HRP. The latter appears to be due to enhanced transport to a late endosomal/prelysosomal degradative compartment that is monensin sensitive. Enhancement of uptake by Rab7 appears to function via an Rab5-sensitive pathway in oocytes since the stimulatory effect of Rab7 was blocked by coinjection of Rab5:S34N. Stimulation of uptake by Rab5 was blocked by Rab5:S34N but not by Rab7:T22N. Our results suggest that Rab7, while functioning downstream of Rab5, may be rate limiting for endocytosis in oocytes.
ATP-sensitive potassium channels (KATP channels) regulate cell excitability in response to metabolic changes. KATP channels are formed as a complex of a sulfonylurea receptor (SURx), a member of the ATP-binding cassette protein family, and an inward rectifier K ؉ channel subunit (Kir6.x). Membrane phospholipids, in particular phosphatidylinositol (PI) 4,5-bisphosphate (PIP2), activate KATP channels and antagonize ATP inhibition of KATP channels when applied to inside-out membrane patches. To examine the physiological relevance of this regulatory mechanism, we manipulated membrane PIP2 levels by expressing either the wild-type or an inactive form of PI-4-phosphate 5-kinase (PIP5K) in COSm6 cells and examined the ATP sensitivity of coexpressed K ATP channels. Channels from cells expressing the wild-type PIP5K have a 6-fold lower ATP sensitivity (K 1͞2, the half maximal inhibitory concentration, Ϸ 60 M) than the sensitivities from control cells (K1͞2 Ϸ 10 M). An inactive form of the PIP5K had little effect on the K1͞2 of wild-type channels but increased the ATP-sensitivity of a mutant KATP channel that has an intrinsically lower ATP sensitivity (from K 1͞2 Ϸ 450 M to K1͞2 Ϸ 100 M), suggesting a decrease in membrane PIP2 levels as a consequence of a dominant-negative effect of the inactive PIP5K. These results show that PIP5K activity, which regulates PIP 2 and PI-3,4,5-P3 levels, is a significant determinant of the physiological nucleotide sensitivity of KATP channels.
Pseudomonas aeruginosa exoenzyme S (ExoS) is an ADP-ribosyltransferase that modifies low-molecularweight GTPases. Here we studied the effect of Rab5 ADP-ribosylation by ExoS on its cellular function, i.e., regulation of early endocytic events. Coculture of CHO cells with P. aeruginosa induced a marked decrease in horseradish peroxidase (HRP) uptake compared to noninfected cells, while coculture with a P. aeruginosa mutant strain that fails to produce ExoS did not lead to any change in HRP uptake. Microinjection of recombinant ExoS into Xenopus oocytes induced strong inhibition of basal HRP uptake by oocytes. Moreover, coinjection of recombinant ExoS with Rab5 abolished the typical stimulation of HRP uptake obtained after GTPase microinjection. Cytosols prepared from injected oocytes were used in an endosome-endosome fusion assay. Cytosol from ExoS-microinjected oocytes was ineffective in promoting endosome-endosome fusion. However, in these conditions, the addition of Rab5 to the assay led to fusion recovery. Finally, we found that the interaction of Rab5 with EEA1 was markedly diminished after Rab5 ADP-ribosylation by ExoS.
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