Ferromagnetic isolation of endosomes: a novel method for subcellular fractionation of Xenopus oocytes

A novel method has been developed using ferric particles to label endosomes, and to achieve magnetic sorting of the various endocytic compartments involved in lipoprotein uptake into cells. Ferric particles conjugated to a receptor-recognized ligand are bound to coated membrane pits and become internalized into the cytoplasm inside coated vesicles. After apparent fusion of the vesicles to tubular endosomes, the conjugates accumulate and finally discharge into multivesicular endosomes. Pulse-chase experiments elucidate the pathway of internalized conjugates and allow both early compartments (pinosomes and tubular endosomes) and late compartments (multivesicular endosomes and storage organelles) to be selectively labelled. After ferroloading of the various transport compartments, the cells are homogenized and subcellularly fractionated. Sorting of labelled endosomes is performed by a specially designed "free-flow" magnetic chamber. Prophase I-arrested oocytes of the toad Xenopus laevis are used as a model system for studying the transport pathway and the conversion of the yolk precursor vitellogenin. It is possible to follow the route of internalization of vitellogenin-iron conjugates via coated pits, coated vesicles, uncoated vesicles, tubular endosomes, multivesicular endosomes, and light primordial yolk platelets. These endosomes shuttle the ferric particles together with the vitellogenin from oolemma to performed heavy yolk organelles which are still growing. In addition, these various compartments can be isolated according to their function and subjected to electron microscopy and to gel electrophoresis for detailed characterization of their limiting membranes as well as their contents.     

In Vivo Study of Vitellogenin-Gold Transport in the Ovarian Follicle and Oocyte of Xenopus laevis

The transport of injected vitellogenin (VTG)-gold in the ovarian follicle and developing oocyte in Xenopus is described. The gold particles reached the extracellular spaces of the theca and interfollicular spaces within 1 and 2 hr, respectively, after a tracer injection at 20°C. The tracers moved through channels between the constitutive cells of both the capillary endothelium and the follicle cell layer.
Compartments in the peripheral cytoplasm of vitellogenic oocytes at stage IV, which relate to yolk formation, seemed to be segregated as follows: (a) internalization compartment consisting of coated pits and vesicles of the oolemma covering the oocyte "macrovilli", (b) transport compartment of endosomes and multivesicular endosomes in the oocyte cortex, and (c) crystallization compartment of primordial yolk platelets (PYP) in the sub-cortical region. The gold particles appeared in the internalization and transport compartments at 3–6 hr after the tracer injection and in the cystallization compartment at 12–18 hr. The VTG, internalized by receptor-mediated endocytosis, was transferred from coated vesicles to multivesicular endosomes by vesicle-to-vesicle fusion. VTG crystallization took place in globular-shaped PYPs of about 1 μm. At 24 hr after the tracer injection, the gold particles appeared in completely crystallized yolk platelets, most of them clustered in the superficial layer and some integrated into the crystals.     

Intracellular transport of vitellogenin in Xenopus oocytes: An autoradiographic study

The role of primordial yolk platelets (PYPs) in the transport of the yolk precursor vitellogenin to the yolk platelets in Xenopus laevis oocytes has been demonstrated by electron microscopic autoradiography. Within 20 min after exposure of the oocyte to ³H-labeled-vitellogenin, silver grains are associated with small PYPs which are formed by the fusion of endosomes. At 40 min after incorporation of ³H-labeled vitellogenin, autoradiographic silver grains are associated with larger PYPs and with the superficial layer of yolk platelets. Thus, the results demonstrate that PYPs are an intermediate in the transport of vitellogenin from endosomes to yolk platelets. These observations are consonant with the general hypothesis that vitellogenin first associates (binds?) with the plasma membrane, then is incorporated by endocytosis into endosomes which fuse to form PYPs, and finally the contents of the PYPs are eventually deposited into yolk platelets.     

Pathway and kinetics of vitellogenin-gold internalization in the Xenopus oocyte

After in vitro incubation of Xenopus oocytes with vitellogenin (VTG)-gold conjugate, the gold particles are distributed on the whole plasma membrane. Their concentration in coated pits still occurs at 0 degrees C. At +20 degrees C the label quickly (30 sec) appears in multi-vesicular endosomes (MVE) which segregate together with primary endocytic vesicles into distinct clusters below the plasma membrane. From this step up to crystallization of the yolk platelets, the gold particles stay in the same compartment. During 5.5 h the label progressively increases along the MVE membrane, first (1.5 h) by fusion of primary endocytic vesicles with consecutively enlarging endosomes, then (4 h) by decreasing of the MVE membrane. As concerns the yolk platelet formation, concentration of primordial yolk platelets (PYP) occurs at 5.5 h from the incubation onset, the labeling of preexisting yolk platelets starts at 7 h, while crystallization of PYP begins only after 12-13 h. Our results indicate that VTG receptors are not preclustered in coated pits and their lateral translation is not inhibited at 0 degrees C. The yolk protein processing takes place within one compartment only. The VTG condensation begins with a long concentration phase of receptor-VTG complexes still integrated in the endosome membrane. It occurs in MVE by: i) a repeated fusion of primary endocytic vesicles; ii) removing part of the endosome membrane by internal vesiculation. Fusion between endosomes occurs only after VTG has dissociated from its receptors and VTG dissociates only when when the density of the VTG-receptor complexes in the endosome membrane is sufficient. Crystallization begins after a 7-8 h delay. The endosome migration into the oocyte is also controlled by the binding of VTG to its receptors. Our results also demonstrate that binding of VTG colloidal gold modifies neither the vitellogenic pathway nor the duration of the vitellogenin internalization. However when vitellogenin is bound to colloidal gold, dissociation of ligand-receptor complexes is delayed because the amount of ligand in the incubation medium is necessarily low.     

Multivesicular bodies play a key role in vitellogenin endocytosis by Xenopus oocytes

A combination of electron microscopic tracers and subcellular fractionation has been used to examine the endocytic pathway of the yolk protein precursor, vitellogenin (VG), in Xenopus oocytes. VG was adsorbed to colloidal gold, and the organelles traversed by newly internalized ligand were examined at various time intervals after endocytosis. VG-Au enters oocytes via coated pits and vesicles and then appears rapidly in tubular endosomes and multivesicular bodies (MVBs). MVBs play a central role in VG processing for storage; the large majority of newly internalized VG enters this compartment, remaining there for up to several hours. Condensation of VG into crystalline bodies begins in MVBs, and continues with growth of the crystals until typical platelets are formed. When oocytes are exposed to high [VG], MVBs containing large amounts of internalized VG are morphologically indistinguishable from the primordial yolk platelets described earlier (Dumont, 1978). The use of VG-Au particles of two sizes demonstrates that gold particles in early MVBs were generally associated with the limiting membrane of these organelles, while older MVB compartments have gold particles well separated from the limiting membranes, suggesting that dissociation of VG from its receptor occurs in this compartment. Newly internalized ligand preferentially forms a new MVB, rather than fusing and mixing with previously formed MVBs. Progressive yolk protein condensation gradually transforms MVBs into yolk platelets over a period of several hours. Analysis of 125I-VG-Au behavior after sucrose gradient fractionation of oocytes allowed correlation of biochemical compartments with those observed in the electron microscope. MVBs containing yolk in progressive stages of condensation were found at densities from 1.16 up to 1.21 g/cc. The final, rate-limiting step in VG transport is a shift of ligand from light (1.21 g/cc) to heavy (1.23 g/cc) platelet compartments (Wall and Meleka, 1985). The morphological correlate of this process is movement of VG-Au from small (less than 3-4 microns diameter) to large (greater than 4 microns diameter) platelets.     

Cathepsin D Activity in the Vitellogenesis of Xenopus laevis

An ovarian extract of Xenopus laevis exhibited in SDS-PAGE analyses an activity cleaving vitellogenin to lipovitellins under mildly acidic conditions. This activity was pepstatin-sensitive and inhibited by monospecific anti-rat liver cathepsin D antibody and thus identified as cathepsin D. Immunoblot analysis showed that two proteins of 43 kDa and 36 kDa immunoreacted with the antibody.
Immunocytochemical staining revealed that the enzyme was located in the cortical cytoplasm of stage I and II oocytes and in small yolk platelets and nascent forms of large yolk platelets in the cortical cytoplasm of stage III oocytes. In stage IV and V oocytes, small yolk platelets retained the immuno-staining but large yolk platelets decreased it. No immuno-positive signals were observed in oocytes at stage VI. When examined by immunoelectron microscopy, gold particles indicated that cathepsin D was located on dense lamellar bodies in the cortical cytoplasm of stage I and II oocytes. The particles were located on primordial yolk platelets and on the superficial layer of small yolk platelets in stage III oocytes, while they were sparse or not present at all on large yolk platelets in stage IV and V oocytes. These results indicate that cathepsin D plays a key role in vitellogenesis by cleaving endocytosed vitellogenin to yolk proteins in developing oocytes.     

An unusual lysosome compartment involved in vitellogenin endocytosis by Xenopus oocytes

We have investigated the lysosomal compartment of Xenopus oocytes to determine the possible role of this organelle in the endocytic pathway of the yolk protein precursor, vitellogenin. Oocytes have lysosome-like organelles of unusual enzymatic composition at all stages of their development, and the amount of hydrolase activity increases steadily throughout oogenesis. These unusual lysosomes appear to be located primarily in a peripheral zone of oocyte cytoplasm. At least two distinct populations of lysosomal organelles can be identified after sucrose density gradient fractionation of vitellogenic oocytes. Most enzyme activity resides in a compartment of large size and high density that appears to be a subpopulation of yolk platelets that are less dense than most platelets within the cell. The appearance of this high density peak of lysosomal enzyme activity coincides with the time of onset of vitellogenin endocytosis during oocyte development. The data suggest that endocytic vesicles that contain vitellogenin fuse with modified lysosomes shortly after their internalization by the oocyte. Pulse-chase experiments with radiolabeled vitellogenin suggest that the ligand passes through the low density platelet compartment en route to the heavy platelets. The accumulation of yolk proteins apparently results from a failure of these molecules to undergo complete digestion after their entry into an unusual lysosomal compartment. The yolk platelets that these proteins finally enter for prolonged storage appear to be a postlysosomal organelle.     

Localization and Characterization of Lectins in Yolk Platelets of Xenopus Oocytes

The localization and characteristics of yolk platelet lectins (YLs) in Xenopus laevis oocytes were studied with antiserum against cortical granule lectins (CGLs) as a probe. In oocytes at stages I, II and III-IV, specific, immunofluorescent staining for the lectins was observed on the cortical cytoplasm extending about 2, 4 and 20 μm, respectively, from the egg surface. In stage III-IV oocytes, the superficial layer of the yolk platelets was also stained. The cortical cytoplasm included cortical granules, coated pits, coated vesicles, multivesicular bodies and primordial yolk platelets. The YLs were incorporated into the oocytes by endocytosis as demonstrated using gold-labeled YLs. On PAGE, native YLs gave two bands of CGL-like proteins and proteins that appeared as a single diffuse band. The YLs and the CGLs shared antigenicity and hemagglutination activity specific to D-galactoside residues. However, the proteins of the diffuse band had little or no activity for either hemagglutination or jelly-precipitation, suggesting that they were monomers with a single reactive site. These results indicate that the YLs are supplied to the oocytes, presumably from extracellular sources, polymerized to CGL-like molecules in the cortical cytoplasm and accumulated in the superficial layer of the yolk platelets.     

Specific proteolysis regulates fusion between endocytic compartments in Xenopus oocytes

We examined the role of proteolytic ligand modification in endosomal targeting using vitellogenin (VTG) uptake by Xenopus oocytes as a model system. Non-cleavable VTG is internalized, but does not appear in yolk platelets. We identified two inhibitors of VTG processing into the yolk proteins: the ionophore monensin and pepstatin A, a specific inhibitor of cathepsin D. Pepstatin neither affected ligand binding and internalization, nor inhibited the degradation of nonspecifically incorporated proteins, whereas monensin inhibited all of these processes. Inhibiting VTG processing prevented its deposition into yolk platelets by strongly interfering with endosome-yolk platelet fusion. Monensin treatment resulted in morphologically abnormal endosomes, while pepstatin only inhibited VTG cleavage and the subsequent fusion of endosomes with yolk platelets. Since VTG cleavage is initiated prior to its deposition in platelets, we postulate that ligand proteolysis could be necessary for normal endosomal targeting.     

Expression of the chicken hepatic glycoprotein receptor in Xenopus oocytes: conservation of ligand and receptor targeting signals.

We have obtained expression of the beta-N-acetylglucosamine-binding receptor from chicken hepatocytes in Xenopus oocytes by injecting mRNA synthesized in vitro from a full length cDNA cloned into an expression vector (Mellow et al: J. Biol Chem 263: 5468-5473, 1988). Immunoprecipitation of the receptor after labeling of oocytes with [35S]-methionine for times ranging from 6 to 72 h revealed 4-5 closely spaced bands of 25-30 kDa after SDS-PAGE. Although these bands were largely resistant to endoglycosidase H cleavage, endoglycosidase F reduced the size of all bands to a single species at 23-24 kDa, indicating that they resulted from heterogeneity in glycosylation of a single polypeptide. Incubation of oocytes expressing this receptor with [125I]-GlcNAc-BSA resulted in 1.8 to 10 x higher levels of cell-associated ligand in mRNA-injected vs. water-injected control oocytes, 2-35% of cell-associated counts was removed by EGTA rinse at 20 degrees C, suggesting that most ligand was inaccessible (presumably intracellular). Immunoprecipitation of sucrose gradient fractions detected receptor molecules predominantly in a light organelle at 1.09-1.12 g/cc (the density of early endosomes and plasma membrane vesicles), with no evidence of the receptor in much heavier yolk platelet fractions even in the presence of ligand. In contrast, internalized [125I]-GlcNAc-BSA was found either at the top of the gradients or in organelles at 1.09-1.17 g/cc and in yolk platelets. TCA precipitation indicated that much intracellular ligand was degraded to acid-soluble fragments. Addition of vitellogenin (the yolk protein precursor) to the medium together with the [125I]-GlcNAc-BSA shifted much of the ligand into yolk platelets. These data indicate that the chicken glycoprotein receptor expressed in oocytes mediates binding and internalization of this ligand into an organelle in which ligand-receptor dissociation occurs, allowing for separation of these two molecules into different compartments. The behavior of ligand in Xenopus oocytes expressing the chicken receptor closely resembles its behavior in hepatocytes.     

Ultrastructural studies of male-incubated ovaries of the gypsy moth,Lymantria dispar

Ovaries from Lymantria dispar females were transplanted into an environment lacking the vitellogenin ligand; i.e., the male milieu. Transmission electron micrographs comparing the terminal oocytes of male-grown ovaries and normal ovaries showed that yolk sphere diameters were reduced in the male-grown oocytes. However, there were larger numbers of these small yolk spheres per unit area of cytoplasm, indicating that the coalescence of endosomes into yolk spheres is reduced in the absence of vitellogenin. Although there are larger numbers of yolk spheres in male-grown oocytes, the smaller diameter of yolk spheres resulted in less area being taken up by yolk spheres per unit area of cytoplasm in male-grown oocytes, yielding lowered yolk production. This lowered yolk production is a result at least in part of the lowered number of coated vesicles per unit area of submembrane space and in part of the reduced interfollicular spaces seen in male-grown ovaries.     

Chicken oocyte growth: receptor-mediated yolk deposition

During the rapid final stage of growth, chicken oocytes take up massive amounts of plasma components and convert them to yolk. The oocyte expresses a receptor that binds both major yolk lipoprotein precursors, vitellogenin (VTG) and very low density lipoprotein (VLDL). In the present study, in vivo transport tracing methodology, isolation of coated vesicles, ligand- and immuno-blotting, and ultrastructural immunocytochemistry were used for the analysis of receptor-mediated yolk formation. The VTG/VLDL receptor was identified in coated profiles in the oocyte periphery, in isolated coated vesicles, and within vesicular compartments both outside and inside membrane-bounded yolk storage organelles (yolk spheres). VLDL particles colocalized with the receptor, as demonstrated by ultrastructural visualization of VLDL-gold following intravenous administration, as well as by immunocytochemical analysis with antibodies to VLDL. Lipoprotein particles were shown to reach the oocyte surface by passage across the basement membrane, which possibly plays an active and selective role in yolk precursor accessibility to the oocyte surface, and through gaps between the follicular granulosa cells. Following delivery of ligands from the plasma membrane into yolk spheres, proteolytic processing of VTG and VLDL by cathepsin D appears to correlate with segregation of receptors and ligands which enter disparate sub-compartments within the yolk spheres. In small, quiescent oocytes, the VTG/VLDL receptor was localized to the central portion of the cell. At onset of the rapid growth phase, it appears that this pre-existing pool of receptors redistributes to the peripheral region, thereby initiating yolk formation. Such a redistribution mechanism would obliterate the need for de novo synthesis of receptors when the oocyte's energy expenditure is to be utilized for plasma membrane synthesis, establishment and maintenance of intracellular topography and yolk formation, and preparation for ovulation.     

Activin incorporation into vitellogenic oocytes of Xenopus laevis.

Activin uptake into Xenopus oocytes was studied by several complementary methods. Immunocytochemistry of adult ovary localized activin and follistatin in the cytoplasm of vitellogenic oocytes and surrounding follicle cells. Surface plasmon resonance analysis of protein interaction kinetics indicated that while follistatin or a complex of activin-follistatin bound to yolk vitellogenin, activin alone did not. Radioactive tracer analysis measured specific incorporation of activin by viable oocytes in vitro. Together, the results suggest that vitellogenic oocytes can import activins from follicle cells and that follistatin may act as a chaperone for binding activin to vitellogenin in yolk platelets.     

Vitellogenin transport and yolk formation in the quail ovary

Morphological and biochemical investigations were made on the yolk formation in ovaries of the quail Coturnix japonica. Morphologically, two ways of nutrient uptake were observed in follicles. In small oocytes of white follicles, vitellogenin (VTG) was taken up through fluid-phase endocytosis which was assisted by follicular lining bodies. The lining bodies were produced in follicle cells. They adhered to the lateral cell membrane, moved along the membrane in the direction of the enclosed oocyte and were posted to the tips of the microvilli. These tips, now with lining bodies, were pinched off from the main cell body, engulfed by indented cell membranes of the oocyte, and transported to yolk spheres. In large oocytes of yellow follicles, VTG and very-low-density lipoproteins (VLDL) were taken up through receptor-mediated endocytosis. The VTG and VLDL particles diffused through the huge interspaces between follicle cells, and once in oocytes were transported to yolk spheres via coated vesicles. Immunohistochemistry showed that the VTG resides on or near the surface of the follicle cell membrane at the zona radiata whereas the cathepsin D resides at or near the oocytic cell membranes. Tubular and round vesicles in the cortical cytoplasm of oocytes were also stained with both antisera, suggesting that these vesicles are the sites where the VTG is enzymatically processed by cathepsin D. Upon analysis by SDS-PAGE, a profile similar to that of yolk-granule proteins was produced by incubating VTG with a quail cathepsin D of 40 kD.     

Female sterile (1) yolkless: a recessive female sterile mutation in Drosophila melanogaster with depressed numbers of coated pits and coated vesicles within the developing oocytes

Ultrastructural analysis of developing oocytes produced by the recessive female sterile mutant, yolkless (yl), in Drosophila melanogaster shows that yl+ gene activity is necessary for coated pit and coated vesicle formation within these oocytes. 29 alleles of the mutation are known to exist, and they fall either within a strongly affected class or a weakly affected class. Analysis of oocytes produced by females homozygous for the strongly affected class of alleles shows a greater than 90% reduction in the numbers of coated pits and coated vesicles. These oocytes have very little proteinaceous yolk, and the females accumulate vitellogenin (the yolk protein precursor) within their hemolymph. Moreover, females homozygous or hemizygous for a given strong allele produce mature oocytes that are flaccid. Alternatively, females homozygous or hemizygous for weak alleles produce yolk-filled oocytes, but the number of coated pits and coated vesicles within these oocytes is 50% of that found in the oocytes of wild-type females. Despite the presence of yolk within these oocytes, females homozygous for weak yl- alleles remain sterile, and their mature oviposited eggs collapse with time.     

Electron microscopic and autoradiographic studies on vitellogenesis in Necturus maculosus

Electron microscope studies on Necturus maculosus oocytes ranging in size from 1.1–1.5 mm in diameter indicate the primary proteinaceous yolk to arise within structures referred to in other amphibian oocytes as yolk precursor sacs or bodies. The origin of these yolk precursor sacs appears to result from the activity of the Golgi complexes which form multivesicular and granular-vesicular bodies, the limiting membrane of which is at times incomplete. During differentiation, the yolk precursor sacs contain small vesicles similar in size to Golgi vesicles, larger vesicles similar to vesicular elements of the agranular endoplasmic reticulum and, on occasion, a portion of a mitochondrion. The interior of these sacs becomes granular, perhaps by a dissolution of the components just described, and soon becomes organized into a crystalline configuration. In oocytes 2.0–2.5 mm in diameter, an extensive micropinocytotic activity begins, continues throughout vitellogenesis, and constitutes the primary mechanism for the formation of secondary yolk protein. Numerous coated and smooth-surfaced vesicles, as well as electron-dense and electronlucent ones, fuse in the cortical ooplasm to form progressively larger yolk platelets.     

The ultrastructure of oogenesis and yolk formation in Labidocera aestiva (Copepoda: Calanoida)

Yolk formation in the oocytes of the free-living, marine copepod, Labidocera aestiva (order Calanoida) involves both autosynthetic and heterosynthetic processes. Three morphologically distinct forms of endogenous yolk are produced in the early vitellogenic stages. Type 1 yolk spheres are formed by the accumulation and fusion of dense granules within vesicular and lamellar cisternae of endoplasmic reticulum. A granular form of type 1 yolk, in which the dense granules within the cisternae of endoplasmic reticulum do not fuse, appears to be synthesized by the combined activity of endoplasmic reticulum and Golgi complexes. Type 2 yolk bodies subsequently appear in the ooplasm but their formation could not be attributed to any particular oocytic organelle. In the advanced stages of vitellogenesis, a single narrow layer of follicle cells becomes more developed and forms extensive interdigitations with the oocytes. Extra-oocytic yolk precursors appear to pass from the hemolymph into the follicle cells and subsequently into the oocytes via micropinocytosis. Pinocytotic vesicles fuse in the cortical ooplasm to form heterosynthetically derived type 3 yolk bodies.     

Differentiation of the animal-vegetal axis in Xenopus laevis oocytes. I. Polarized intracellular translocation of platelets establishes the yolk gradient

The animal-vegetal axis of the oocyte of Xenopus laevis is recognizable not only by the pattern of surface pigmentation, but also by the distribution of yolk platelets, with the largest platelets (congruent to 14 microns in diameter) and 70% of the total yolk protein localized in the vegetal hemisphere. We have used fluorescent and radioactive vitellogenins (yolk protein precursors) to study the spatial and temporal patterns of yolk deposition along this axis. We find that the rate of uptake of vitellogenin is nearly uniform over the surface of vitellogenic oocytes of all sizes. Once formed, yolk platelets in the animal hemisphere move inward, around the germinal vesicle, and into the central region of the vegetal hemisphere. Yolk platelets of the vegetal hemisphere do not actively move but are slowly displaced from the surface by successive layers of younger platelets arising and enlarging near the surface. The oldest yolk platelets, which arise circumcortically at the beginning of vitellogenesis in stage II and III oocytes, eventually come to reside in the vegetal hemisphere of stage VI oocytes, in the upper portion of the cup-shaped region of largest platelets. The vegetal hemisphere thus gains the majority of yolk protein by directed intracellular transport from the animal hemisphere adding to the amount directly sequestered by the vegetal hemisphere.     

Delivery of ligands from sorting endosomes to late endosomes occurs by maturation of sorting endosomes

After endocytosis, lysosomally targeted ligands pass through a series of endosomal compartments. The endocytic apparatus that accomplishes this passage may be considered to take one of two forms: (a) a system in which lysosomally targeted ligands pass through preexisting, long-lived early sorting endosomes and are then selectively transported to long-lived late endosomes in carrier vesicles, or (b) a system in which lysosomally targeted ligands are delivered to early sorting endosomes which themselves mature into late endosomes. We have previously shown that sorting endosomes in CHO cells fuse with newly formed endocytic vesicles (Dunn, K. W., T. E. McGraw, and F. R. Maxfield. 1989. J. Cell Biol. 109:3303-3314) and that previously endocytosed ligands lose their accessibility to fusion with a half-time of approximately 8 min (Salzman, N. H., and F. R. Maxfield. 1989. J. Cell Biol. 109:2097-2104). Here we have studied the properties of individual endosomes by digital image analysis to distinguish between the two mechanisms for entry of ligands into late endosomes. We incubated TRVb-1 cells (derived from CHO cells) with diO-LDL followed, after a variable chase, by diI-LDL, and measured the diO content of diI-containing endosomes. As the chase period was lengthened, an increasing percentage of the endosomes containing diO-LDL from the initial incubation had no detectable diI-LDL from the second incubation, but those endosomes that contained both probes showed no decrease in the amount of diO-LDL per endosomes. These results indicate that (a) a pulse of fluorescent LDL is retained by individual sorting endosomes, and (b) with time sorting endosomes lose the ability to fuse with primary endocytic vesicles. These data are inconsistent with a preexisting compartment model which predicts that the concentration of ligand in sorting endosomes will decline during a chase interval, but that the ability of the stable sorting endosome to receive newly endocytosed ligands will remain high. These data are consistent with a maturation mechanism in which the sorting endosome retains and accumulates lysosomally directed ligands until it loses its ability to fuse with newly formed endocytic vesicles and matures into a late endosome. We also find that, as expected according to the maturation model, new sorting endosomes are increasingly labeled during the chase period indicating that new sorting endosomes are continuously formed to replace those that have matured into late endosomes.(ABSTRACT TRUNCATED AT 400 WORDS)