Phosphatidylinositide 3-kinases (PI 3-kinases) have been implicated in controlling cell proliferation, actin cytoskeleton organization, and the regulation of vesicle trafficking between intracellular organelles. There are at least three genes in Dictyostelium discoideum, DdPIK1, DdPIK2, and DdPIK3, encoding proteins most closely related to the mammalian 110-kD PI-3 kinase in amino acid sequence within the kinase domain. A mutant disrupted in DdPIK1 and DdPIK2 (Δddpik1/ddpik2) grows slowly in liquid medium. Using FITC-dextran (FD) as a fluid phase marker, we determined that the mutant strain was impaired in pinocytosis but normal in phagocytosis of beads or bacteria. Microscopic and biochemical approaches indicated that the transport rate of fluid-phase from acidic lysosomes to non-acidic postlysosomal vacuoles was reduced in mutant cells resulting in a reduction in efflux of fluid phase. Mutant cells were also almost completely devoid of large postlysosomal vacuoles as determined by transmission EM. However, Δddpik1/ddpik2 cells functioned normally in the regulation of other membrane traffic. For instance, radiolabel pulse-chase experiments indicated that the transport rates along the secretory pathway and the sorting efficiency of the lysosomal enzyme α-mannosidase were normal in the mutant strain. Furthermore, the contractile vacuole network of membranes (probably connected to the endosomal pathway by membrane traffic) was functionally and morphologically normal in mutant cells. Light microscopy revealed that Δddpik1/ddpik2 cells appeared smaller and more irregularly shaped than wild-type cells; 1–3% of the mutant cells were also connected by a thin cytoplasmic bridge. Scanning EM indicated that the mutant cells contained numerous filopodia projecting laterally and vertically from the cell surface, and fluorescent microscopy indicated that these filopodia were enriched in F-actin which accumulated in a cortical pattern in control cells. Finally, Δddpik1/ddpik2 cells responded and moved more rapidly towards cAMP. Together, these results suggest that Dictyostelium DdPIK1 and DdPIK2 gene products regulate multiple steps in the endosomal pathway, and function in the regulation of cell shape and movement perhaps through changes in actin organization.
Rho family proteins have been implicated in regulating various cellular processes, including actin cytoskeleton organization, endocytosis, cell cycle, and gene expression. In this study, we analyzed the function of a novel Dictyostelium discoideum Rho family protein (RacC). A cell line was generated that conditionally overexpressed wild-type RacC three- to fourfold relative to endogenous RacC. Light and scanning electron microscopy indicated that the morphology of the RacC-overexpressing cells [RacC WT(+) cells] was significantly altered compared with control cells. In contrast to the cortical F-actin distribution normally observed, RacC WT(+) cells displayed unusual dorsal and peripheral F-actin–rich surface blebs (petalopodia, for flower-like). Furthermore, phagocytosis in the RacC WT(+) cells was induced threefold relative to control Ax2 cells, whereas fluid-phase pinocytosis was reduced threefold, primarily as the result of an inhibition of macropinocytosis. Efflux of fluid-phase markers was also reduced in the RacC WT(+) cells, suggesting that RacC may regulate postinternalization steps along the endolysosomal pathway. Treatment of cells with Wortmannin and LY294002 (phosphatidylinositol 3-kinase inhibitors) prevented the RacC-induced morphological changes but did not affect phagocytosis, suggesting that petalopodia are probably not required for RacC-induced phagocytosis. In contrast, inactivating diacylglycerol-binding motif–containing proteins by treating cells with the drug calphostin C completely inhibited phagocytosis in control and RacC WT(+) cells. These results suggest that RacC plays a role in actin cytoskeleton organization and phagocytosis inDictyostelium.
The mammalian small molecular weight GTPase Rab7 (Ypt7 in yeast) has been implicated in regulating membrane traffic at postinternalization steps along the endosomal pathway. A cDNA encoding a protein 85% identical at the amino acid level to mammalian Rab7 has been cloned from Dictyostelium discoideum. Subcellular fractionation and immunofluorescence microscopy indicated that Rab7 was enriched in lysosomes, postlysosomes, and maturing phagosomes. Cell lines were generated that overexpressed Rab7 wild-type (WT), Rab7 Q67L (constitutively active form), and Rab7 T22N (dominant negative form) proteins. The Rab7 T22N cell line internalized fluid phase markers and latex beads (phagocytosis) at one-third the rate of control cells, whereas Rab7 WT and Rab7 Q67L cell lines were normal in uptake rates but exocytosed fluid phase faster than control cells. In contrast, fluid phase markers resided in acidic compartments for longer periods of time and were more slowly exocytosed from Rab7 T22N cells as compared with control cells. Light microscopy indicated that Rab7-expressing cell lines contained morphologically altered endosomal compartments. Compared with control cells, Rab7 WT-and Rab7 Q67L-expressing cells contained a reduced number of vesicles the size of postlysosomes (>2.5 ,um) and an increased number of smaller vesicles, many of which were nonacidic; in control cells, >90% of the smaller vesicles were acidic. In contrast, Rab7 T22N cells contained an increased proportion of large acidic vesicles relative to nonacidic vesicles. Radiolabel pulse-chase experiments indicated that all of the cell lines processed and targeted lysosomal a-mannosidase normally, indicating the lack of a significant role for Rab7 in the targeting pathway; however, retention of mature lysosomal hydrolases was affected in Rab7 WT and Rab7 T22N cell lines. Contrary to the results observed for the fluid phase efflux experiments, Rab7 T22N cells oversecreted a-mannosidase, whereas Rab7 WT cells retained this hydrolase as compared with control cells. These data support a model that Rab7 may regulate retrograde transport of lysosomal enzymes and the V-type H+-ATPase from postlysosomes to lysosomes coupled with the efficient release of fluid phase from cells.
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