ATP-dependent membrane assembly of F-actin facilitates membrane fusion.

We recently established an in vitro assay that monitors the fusion between latex-bead phagosomes and endocytic organelles in the presence of J774 macrophage cytosol (). Here, we show that different reagents affecting the actin cytoskeleton can either inhibit or stimulate this fusion process. Because the membranes of purified phagosomes can assemble F-actin de novo from pure actin with ATP (), we focused here on the ability of membranes to nucleate actin in the presence of J774 cytosolic extracts. For this, we used F-actin sedimentation, pyrene actin assays, and torsional rheometry, a biophysical approach that could provide kinetic information on actin polymerization and gel formation. We make two major conclusions. First, under our standard in vitro conditions (4 mg/ml cytosol and 1 mM ATP), the presence of membranes actively catalyzed the assembly of cytosolic F-actin, which assembled into highly viscoelastic gels. A model is discussed that links these results to how the actin may facilitate fusion. Second, cytosolic actin paradoxically polymerized more under ATP depletion than under high-ATP conditions, even in the absence of membranes; we discuss these data in the context of the well described, large increases in F-actin seen in many cells during ischemia.

In vitro fusion of phagosomes with different endocytic organelles from J774 macrophages.

We describe novel biochemical and electron microscopy assays to investigate in vitro fusion of latex bead phagosomes with three different endocytic organelle fractions from J774 macrophages. After formation, early phagosomes fuse avidly with early and late endosomes and for a longer period of time with lysosomes, but they subsequently become fusion-incompetent. The fusion of early, but not late, phagosomes with all three endocytic fractions could be significantly stimulated by Rab5. In contrast to other cell types investigated, this Rab is uniquely enriched on both early and late endosomes in J774 macrophages. Moreover, exogenous Rab5 stimulates homotypic fusion between both sets of organelles. This was shown by a quantitative electron microscopy fusion assay that can directly assay fusion between any combination of morphologically defined organelles. By the same approach, we discovered an unexpected Rab5-stimulatable fusion between early and late endosomes in J774, but not in BHK cells. Thus, in J774 cells both Rab5 and the endocytic pathway seem to have evolved additional functions not yet seen in nonphagocytic cells.

Lysosomal enzyme trafficking between phagosomes, endosomes, and lysosomes in J774 macrophages. Enrichment of cathepsin H in early endosomes.

In this study we take advantage of recently developed methods using J774 macrophages to prepare enriched fractions of early endosomes, late endosomes, dense lysosomes, as well as phagosomes of different ages enclosing 1-micron latex beads to investigate the steady state distribution and trafficking of lysosomal enzyme activity between these organelles. At steady state these cells appear to possess four different cellular structures, in addition to phagolysosomes, where acid hydrolases were concentrated. The first site of hydrolase concentration was the early endosomes, which contained the bulk of the cellular cathepsin H. This enzyme was acquired by phagosomes significantly faster than the other hydrolases tested. The second distinct site of lysosomal enzyme concentration was the late endosomes which contain the bulk of cathepsin S. The third and fourth large pools of hydrolases were found in two functionally distinct types of dense lysosomes, only one of which was found to be secreted in the presence of chloroquine or bafilomycin. Among this secreted pool was soluble furin, generally considered only as a membrane-bound trans-Golgi network resident protein. Thus, the organelles usually referred to as "lysosomes" in fact encompass a growing family of highly dynamic but functionally distinct endocytic organelles.

Molecular characterization of phagosomes.

The transformation of newly formed phagosomes into mature phagolysosomes is a process that involves a complex series of interactions between phagosomes and other vacuolar organelles. The machinery required by phagosomes to mediate these interactions is poorly understood. In this study, we allowed human and various rodent cells to take up latex beads whose density facilitates a simple purification of phagosomes using discontinuous sucrose gradients. With this system, we initiated a systematic study of phagosome proteins using two-dimensional gel electrophoresis and the currently available two-dimensional gel protein data bases. By this approach, we were able to recognize a group of polypeptides associated with mouse J774 phagosomes-phagolysosomes including annexin II, annexin VI, the beta-1 and beta-2 subunits of trimeric G proteins, and a group of actin-binding proteins. While the amount of annexin II associated to phagosomes was similar at all times of latex internalization, the levels of annexin VI were higher on late phagosomes. Phospholipid analysis of J774 phagosomes isolated at early and late time points during phagolysosome formation also revealed significant differences in their lipid composition. In the human phagosomes, we resolved over 200 polypeptides on the two-dimensional gels. These included the proteins described in the mouse, as well as 32 polypeptides that were found to be highly enriched in phagosomes, 15 of which are not present in the current data bases. The results demonstrate that the use of latex bead phagosomes is a powerful system to identify key molecules involved in phagolysosome biogenesis.

Evidence for retrograde traffic between terminal lysosomes and the prelysosomal/late endosome compartment.

We have investigated the interactions occurring between the prelysosomal compartment, PLC/late endosome, and terminal lysosomes using an approach that allowed us to internalize and deliver specific tracers to these compartments, and look for evidence of their meeting. After internalization of sucrose, the lysosomes (sucrosomes), but not the PLC/late endosomes, became significantly swollen and visible in the light microscope. If invertase is then added to the medium it reaches the lysosomes where it cleaves sucrose into fructose and glucose. These sugars, unlike sucrose, can be transported into the cytosol, resulting in the disappearance of the sucrosomes. We previously showed that phagocytosed latex beads are delivered specifically to, and reside in, the PLC/late endosome, a stage earlier than the lysosomes in the endocytic pathway (Rabinowitz et al. (1992) J. Cell Biol. 116, 95-112). In the present study, we demonstrate that invertase conjugated to the latex beads, and thus immobilized in late endosomes, has access to the sucrose present in the more distal lysosomes. Experiments using nocodazole indicate that this retrograde fusion event requires the presence of an intact microtubule network. The simplest interpretation of our results is that the two compartments fuse, allowing for a retrograde transport of sucrose from the lysosomes to the PLC/late endosomes.