Individual Endosomes Research Articles

Sequence-Dependent Sorting of Recycling Proteins by Actin-Stabilized Endosomal Microdomains

The functional consequences of signaling receptor endocytosis are determined by the endosomal sorting of receptors between degradation and recycling pathways. How receptors recycle efficiently, in a sequence-dependent manner that is distinct from bulk membrane recycling, is not known. Here, in live cells, we visualize the sorting of a prototypical sequence-dependent recycling receptor, the beta-2 adrenergic receptor, from bulk recycling proteins and the degrading delta-opioid receptor. Our results reveal a remarkable diversity in recycling routes at the level of individual endosomes, and indicate that sequence-dependent recycling is an active process mediated by distinct endosomal subdomains distinct from those mediating bulk recycling. We identify a specialized subset of tubular microdomains on endosomes, stabilized by a highly localized but dynamic actin machinery, that mediate this sorting, and provide evidence that these actin-stabilized domains provide the physical basis for a two-step kinetic and affinity-based model for protein sorting into the sequence-dependent recycling pathway.

Digital fluorescence analysis of trafficking of single endosomes containing low-density lipoprotein in adrenocortical cells: Facilitation of centripetal motion by adrenocorticotropic hormone

Imaging of trafficking of endosomes containing low-density lipoprotein (LDL) is useful to analyze cholesterol transport in adrenocortical cells. At 60min after the application of fluorescently labeled LDL to adrenocortical cells, individual endosomes containing LDL were demonstrated to undergo frequent switching between forward and reverse movement and immobility. The population of moving endosomes (≥0.065μm/s) was approximately 75% in control cells. The remaining endosomes were either slowly moving or temporarily immobile. At 3h after the LDL addition, endosomes were concentrated around the circumference of the cell nuclei. The endosome movement was inhibited by nocodazole, implying that endosomes undergo movement along microtubule networks. Anti-dynein antibodies inhibited the motion of endosomes towards the nucleus, and anti-kinesin antibodies inhibited peripherally directed motion. These results imply that both dynein-like and kinesin-like motor proteins bind to the same endosome, resulting in saltatory movements with centripetal or peripherally directed direction, depending on which motor binds to microtubules. Though the dynein and kinesin motors drive the endosomes very rapidly (μm/s), frequent saltatory motions of single endosomes may induce the very slow net centripetal motion (μm/h).The application of adrenocorticotropic hormone (ACTH) resulted in a facilitation of the centripetal motion of endosomes, resulting in the establishment of the concentration of endosomes around cell nuclei within 1h.

Morphogen Gradient Formation Unraveled Using In Vivo Three-dimensional Single Molecule Microscopy

Positional information is essential for the cell's fate in tissue. In the wing imaginal disk of Drosophila melanogaster positional information is provided by a concentration gradient of the morphogens Decapentaplegic (Dpp) and Wingless. We use a 3D-epifluorescence setup to unravel the spatio-temporal distribution of YFP-labeled Dpp after secretion by specialized producing cells. With our approach we are able to characterize the Dpp distribution in the wing disk in all three dimensions in vivo. Most Dpp is located apically in a layer of ∼5 μm. To elucidate how the gradient is maintained individual endosomes containing Dpp are followed. We found that endosomes contain up to 100 Dpp molecules allowing us to follow endosomes for hundreds of frames with high spatio-temporal accuracy in three dimensions.The Dpp concentration in each endosome was directly determined from the fluorescence intensity. We find a constant Dpp fraction of 60% in endosomes, agreeing with the fixed fraction found in FRAP experiments. Sudden changes in Dpp content of up to 15 Dpp molecules are observed, indicating that Dpp is endocytosed in clusters into vesicles before vesicle fusion with endosomes occurs. Surprisingly multiple preferred Dpp cluster sizes are found. Measuring Dpp in- and outflow results in rates on the order of minutes. Labeling different types of endosomes allows us to calculate Dpp degradation and recycling rates.Endosome mobility plays an important role in maintaining the Dpp gradient. We find that Dpp-containing endosomes close to the Dpp source are transported during 15% of the time. Further away this percentage drops, indicating that transport via endosomes is playing a less important role in maintaining the morphogen gradient. Our study leads to a mechanistic model for gradient formation on the level of the mobility of individual Dpp endosomes and molecules.

Caveolar Endocytosis and Microdomain Association of a Glycosphingolipid Analog Is Dependent on Its Sphingosine Stereochemistry

We have previously shown that glycosphingolipid analogs are internalized primarily via caveolae in various cell types. This selective internalization was not dependent on particular carbohydrate headgroups or sphingosine chain length. Here, we examine the role of sphingosine structure in the endocytosis of BODIPYtrade mark-tagged lactosylceramide (LacCer) analogs via caveolae. We found that whereas the LacCer analog with the natural (D-erythro) sphingosine stereochemistry is internalized mainly via caveolae, the non-natural (L-threo) LacCer analog is taken up via clathrin-, RhoA-, and Cdc42-dependent mechanisms and largely excluded from uptake via caveolae. Unlike the D-erythro-LacCer analog, the L-threo analog did not cluster in membrane microdomains when added at higher concentrations (5-20 microm). In vitro studies using small unilamellar vesicles and giant unilamellar vesicles demonstrated that L-threo-LacCer did not undergo a concentration-dependent excimer shift in fluorescence emission such as that seen with BODIPYtrade mark-sphingolipids with natural stereochemistry. Molecular modeling studies suggest that in d-erythro-LacCer, the disaccharide moiety extends above and in the same plane as the sphingosine hydrocarbon chain, while in L-threo-LacCer the carbohydrate group is nearly perpendicular to the hydrocarbon chain. Together, these results suggest that the altered stereochemistry of the sphingosine group in L-threo-LacCer results in a perturbed structure, which is unable to pack closely with natural membrane lipids, leading to a reduced inclusion in plasma membrane microdomains and decreased uptake by caveolar endocytosis. These findings demonstrate the importance of the sphingolipid stereochemistry in the formation of membrane microdomains.

Ligands for Clathrin-Mediated Endocytosis Are Differentially Sorted into Distinct Populations of Early Endosomes

Cells rely on the correct sorting of endocytic ligands and receptors for proper function. Early endosomes have been considered as the initial sorting station where cargos for degradation separate from those for recycling. Using live-cell imaging to monitor individual endosomes and ligand particles in real time, we have discovered a sorting mechanism that takes place prior to early endosome entry. We show that early endosomes are in fact comprised of two distinct populations: a dynamic population that is highly mobile on microtubules and matures rapidly toward late endosomes and a static population that matures much more slowly. Several cargos destined for degradation are preferentially targeted to the dynamic endosomes, whereas the recycling ligand transferrin is nonselectively delivered to all early endosomes and effectively enriched in the larger, static population. This pre-early endosome sorting process begins at clathrin-coated vesicles, depends on microtubule-dependent motility, and appears to involve endocytic adaptors.

Rab7 Activity Affects Epidermal Growth Factor:Epidermal Growth Factor Receptor Degradation by Regulating Endocytic Trafficking from the Late Endosome

The epidermal growth factor receptor (EGFR) is a member of the receptor tyrosine kinase family. Ligand (epidermal growth factor or EGF) binding to the EGFR results in the coordinated activation and integration of biochemical signaling events to mediate cell growth, migration, and differentiation. One mechanism the cell utilizes to orchestrate these events is ligand-mediated endocytosis through the canonical clathrin-mediated endocytic pathway. Identification of proteins that regulate the intracellular movement of the EGF.EGFR complex is an important first step in dissecting how specificity of EGFR signaling is conferred. We examined the role of the small molecular weight guanine nucleotide-binding protein (G-protein) rab7 as a regulator of the distal stages of the endocytic pathway. Through the transient expression of activating and inactivating mutants of rab7 in HeLa cells, we have determined that rab7 activity directly correlates with the rate of radiolabeled EGF and EGFR degradation. Furthermore, when inhibitory mutants of rab7 are expressed, the internalized EGF.EGFR complex accumulates in high-density endosomes that are characteristic of the late endocytic pathway. Thus, we conclude that rab7 regulates the endocytic trafficking of the EGF.EGFR complex by regulating its lysosomal degradation.

Rab Conversion as a Mechanism of Progression from Early to Late Endosomes

The mechanisms of endosome biogenesis and maintenance are largely unknown. The small GTPases Rab 5 and Rab 7 are key determinants of early and late endosomes, organizing effector proteins into specific membrane subdomains. Whether such Rab machineries are indefinitely maintained on membranes or can disassemble in the course of cargo transport is an open question. Here, we combined novel image-analysis algorithms with fast live-cell imaging. We found that the level of Rab 5 dynamically fluctuates on individual early endosomes, linked by fusion and fission events into a network in time. Within it, degradative cargo concentrates in progressively fewer and larger endosomes that migrate from the cell periphery to the center where Rab 5 is rapidly replaced with Rab 7. The class C VPS/HOPS complex, an established GEF for Rab 7, interacts with Rab 5 and is required for Rab 5-to-Rab 7 conversion. Our results reveal unexpected dynamics of Rab domains and suggest Rab conversion as the mechanism of cargo progression between early and late endosomes.

Digital Fluorescence Imaging of Trafficking of Endosomes Containing Low-Density Lipoprotein in Brain Astroglial Cells

We have used digital fluorescence microscopy to examine transport of LDL-containing endosomes in rat brain astroglial cells to show that individual middle endosomes undergo rapid transitions between forward/backward movements and immobile states over short distances. The population of rapidly moving endosomes (>0.04 μm/sec) was 35.9%, and the remaining endosomes were slowly moving or temporarily immobile (<0.04 μm/sec). The averaged motion was, however, a very slow perinuclear motion with a velocity of 3.25 μm/h. This small velocity is mainly due to frequent changing of directions in movements, requiring 6 h for a significant concentration around the circumference of the cell nuclei. The application of both anti-dynein antibodies and vanadate in permeabilized cells resulted in peripherally concentrated distribution of endosomes, probably due to inhibition of perinuclear motion by dynein-like motor proteins. These results imply that both dynein-like and kinesin-like proteins bind to the same endosome resulting in both perinuclear and peripherally directed movements.

Internalization and sorting of plasma membrane sphingolipid analogues in differentiating oligodendrocytes.

We studied the formation of early endosomes in differentiating oligodendrocytes and type-2 astrocytes, which are derived from common precursor cells in rat neonates, using fluorescent analogues of lactosylceramide (LacCer) and sulfatide labeled with 4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene++ +-3-pentanoic acid (BODIPY FL C5). These sphingolipid analogues exhibit a concentration-dependent shift in their fluorescence emission maximum from green to red wavelengths that can be used to estimate the relative concentration of an analogue in the intracellular membranes of living cells by quantitative fluorescence microscopy. When oligodendrocytes at various stages of differentiation were incubated with 1 microM BODIPY-sphingolipid at 10 degrees C and washed, yellow/green plasma membrane fluorescence was observed. Quantitative studies confirmed that the amount of BODIPY-LacCer or -sulfatide incorporated into the plasma membrane of a given cell type was identical. When these cells were subsequently warmed to 37 degrees C for 2-10 min to allow internalization to occur, the BODIPY-sphingolipid analogues were distributed in a punctate pattern throughout the cytoplasm. Within individual cells labeled with BODIPY-sulfatide, some endosomes exhibited green fluorescence, whereas others emitted red/orange fluorescence. In contrast, when BODIPY-LacCer was used, only green endosomes were observed. Although this phenomenon could be observed at earlier stages of differentiation, it was most obvious in mature oligodendrocytes, where quantitative measurements of the red/green ratio of individual endosomes suggested about a threefold difference between the concentration of the LacCer and sulfatide analogues in endosomes. These results suggest that "lipid sorting" takes place during endocytosis in mature oligodendrocytes, resulting in selective exclusion of certain lipid species during the internalization process. This sorting event may result in the net addition of lipids to the differentiated oligodendrocyte plasma membrane.

Intracellular pathways and degradation of endosomal contents in basal epithelial cells of freshwater sponges (Porifera, Spongillidae)

The digestive system expressed by basal epithelial cells of the freshwater sponges Spongilla lacustris and Ephydatia muelleri is mainly represented by a population of 30–50 preexisting lysosomes located in the close vicinity of the central nucleus. The strongly acidic vacuoles (pH 4–4.5) vary in size between 1 and 3 μm, and contain a set of different lysosomal enzymes. Immunocytochemical studies succeeded in the detection of β-hexosaminidase, cathepsin D, acid phosphatase, and α-glucosidase. Endosomes resulting from fluid-phase macropinocytosis, receptor-mediated endocytosis, or phagocytotic activity deliver their exogenous contents to the preexisting lysosomes for enzymatic degradation. Macropinosomes and phagosomes follow a rather reduced intracellular pathway by immediate fusion with the lysosomal compartment, whereas substances conveyed by coated vesicles pass through two additional vacuolar stages, namely early and late endosomes. Early endosomes serve as sorting organelles and segregate various constituents of complex ligands (BSA-AU6, BSA-AU12) by size into individual late endosomes, which then coalesce with preexisting lysosomes. As a whole, the intracellular pathways and hydrolytic processing of endosomal and phagosomal contents in freshwater sponge cells share certain similarities with the respective mechanisms in cells of higher eukaryotes.

Increased Neuronal Endocytosis and Protease Delivery to Early Endosomes in Sporadic Alzheimer’s Disease: Neuropathologic Evidence for a Mechanism of Increased β-Amyloidogenesis

The early endosome is the first vacuolar compartment along the endocytic pathway. It is the site of internalization and initial processing of amyloid precursor protein (APP) and apolipoprotein E (ApoE), two proteins of etiological importance in Alzheimer's disease, and a putative site of beta-amyloid peptide (Abeta) formation. Here, we identify early endosomes in human pyramidal neurons, using specific compartmental markers and morphometry, and show that in Alzheimer's disease individual endosomes display up to 32-fold larger volumes than the normal average. Endosomal enlargement contributed to an average 2.5-fold larger total endosomal volume per neuron, implying a marked increase in endocytic activity. Endosomal alterations were evident in most pyramidal neurons in Alzheimer brain, detectable at early stages of the disease but absent in several other neurodegenerative disorders examined. In addition, mature and proenzyme forms of the proteases cathepsin B and cathepsin D, a candidate APP secretase, were identified in most early endosomes in Alzheimer brains but were detectable in only a minor proportion of endosomes in normal brain. Expression of the cation-dependent 46 kDa mannose 6-phosphate receptor was elevated in pyramidal neurons of Alzheimer brains, which could be a possible basis for the altered cathepsin trafficking pattern. Enhanced endocytic activity, coupled with increased trafficking to endosomes of proteases, which may have the ability under pathological conditions to generate Abeta, constitutes a potential mechanism by which beta-amyloidogenesis may become accelerated in sporadic AD and also be subject to influences by ApoE.

Evidence against Defective trans-Golgi Acidification in Cystic Fibrosis

Defective organelle acidification has been proposed as a unifying hypothesis to explain the pleiotropic cellular abnormalities associated with cystic fibrosis. To test whether cystic fibrosis transmembrane conductance regulator (CFTR) participates in trans-Golgi pH regulation, intraluminal trans-Golgi pH was measured in stably transfected Swiss 3T3 fibroblasts (expressing CFTR or DeltaF508-CFTR) and CFTR-expressing and nonexpressing epithelial cells. trans-Golgi pH was measured by ratio-imaging confocal microscopy using a liposome injection procedure to label the lumen of trans-Golgi with fluid phase fluorescein and rhodamine chromophores (Seksek, O., Biwersi, J., and Verkman, A. S.(1995) J. Biol. Chem. 270, 4967-4970). Selective labeling of trans-Golgi was confirmed by colocalization of the delivered fluid phase fluorophores with N-(6-[(7-nitrobenzo-2-oxa-1, 3-diazol-4-yl)amino]caproyl)-sphingosine. In unstimulated fibroblasts in HCO3--free buffer, trans- Golgi pH was 6.25 +/- 0.04 (mean +/- S.E.; n = 80, vector control), 6.30 +/- 0.03 (n = 74, CFTR) and 6.23 +/- 0.06 (n = 60, DeltaF508) (not significant). After stimulation of plasma membrane Cl- conductance by 8-(4-chlorophenylthio)-cAMP (CPT-cAMP), trans-Golgi pH was 6.42 +/- 0.07 (n = 22, control), 6.47 +/- 0.07 (n = 20, CFTR), and 6.35 +/- 0. 07 (n = 22, DeltaF508) (not significant). Similarly, significant pH differences were not found for control versus CFTR-expressing cells in 25 mM HCO3- buffer. In epithelial cells, which do not express CFTR, trans-Golgi pH was (in 25 mM HCO3-) 6.36 +/- 0.04 (n = 33) and 6.34 +/- 0.08 (n = 23, CPT-cAMP) in MDCK cells and 6.25 +/- 0.04 (n = 18) and 6.24 +/- 0.06 (n = 15, CPT-cAMP) in SK-MES-1 cells. In Calu-3 cells, which natively express CFTR, trans-Golgi pH was (in 25 mM HCO3-) 6.19 +/- 0.05 (n = 25) and 6.17 +/- 0.08 (n = 23, CPT-cAMP). To test whether CFTR expression affects pH in the endosomal compartment in HCO3- buffer, pH was measured by ratio imaging in individual endosomes labeled with fluorescein-rhodamine dextrans. Comparing control and CFTR-expressing fibroblasts, average endosome pH (range, 5.40-5.53 after 10 min; 4.79-4.89, 30 min) differed by <0.13 unit, both before and after cAMP stimulation. These results indicate that CFTR expression and activation do not influence pH in the trans-Golgi and endosomal compartments, providing direct evidence against the defective acidification hypothesis.

Imaging of endosome fusion in BHK fibroblasts based on a novel fluorimetric avidin-biotin binding assay

A fluorescence assay of in vivo endosome fusion was developed and applied to define the kinetics of endosome fusion in baby hamster kidney (BHK) fibroblasts. The assay is based on an approximately 10-fold enhancement of the green fluorescence of BODIPY-avidin upon biotin binding. The BODIPY-avidin fluorescence enhancement occurred in < 25 ms, was pH-independent, and involved a BODIPY-tryptophan interaction. For endocytosis in vivo, BHK fibroblasts were pulse-labeled with BODIPY-avidin together with a red (rhodamine) fluorescent fusion-independent chromophore (TMR). After specified chase times in a nonfluorescent medium, a second cohort of endosomes was pulse-labeled with biotin-conjugated albumin, dextran, or transferrin. Fusion of biotin-containing endosomes with avidin-containing endosomes was quantified by ratio imaging of BODIPY-to-TMR fluorescence in individual endosomes, using imaging methods developed for endosome pH studies. Analysis of BODIPY-to-TMR ratio distributions in avidin-labeled endosomes exposed to zero and maximum biotin indicated > 90% sensitivity for detection of endosome fusion. In avidin pulse (10 min) -chase-biotin albumin pulse (10 min) studies, both fused and unfused endosomes were identified; the fractions of avidin-labeled endosomes that fused with biotin-labeled endosomes were 0.48, 0.21, 0.16, and 0.07 for 0-, 5-, 10-, and 20-min chase times. Fitting of fusion data to a mathematical model of in vivo endosome fusion required the existence of an intermediate fusion compartment. Pulse-chase studies performed with biotin-transferrin to label the early/recycling endosomes indicated that after a 10-min chase, avidin-labeled endosomes reached a compartment that was inaccessible to biotin-transferrin. The assay was also applied to determine whether endosome fusion was influenced by temperature, pH (bafilomycin A1), second messengers (cAMP agonists, phorbol 12-myristate 13-acetate, staurosporine), and growth-related factors (platelet-derived growth factor, genistein). The results establish a sensitive fluorescence assay to quantify the fusion of vesicular compartments in living cells.

Functional CFTR in endosomal compartment of CFTR-expressing fibroblasts and T84 cells.

It was proposed that the cystic fibrosis transmembrane conductance regulator (CFTR) functions in the endosomal compartment as a adenosine 3',5'-cyclic monophosphate (cAMP)-regulated Cl channel that regulates endosomal acidification (J. Barasch, B. Kiss, A. Prince, L. Saiman, D. Gruenert, and A. Al-Awqati, Nature Lond. 352: 70-73, 1991). This hypothesis was tested in stably transfected Swiss 3T3 fibroblasts expressing CFTR or delta F508 CFTR and in T84 epithelial cells that normally express CFTR. In fibroblasts, the time course of pH in individual endosomes was measured by quantitative image analysis after 1 min pulse labeling with 2 microM carboxyfluorescein (Cf)-tetramethylrhodamine-transferrin (K. Zen, J. Biwersi, N. Periasamy, and A. S. Verkman. J. Cell Biol. 119: 99-110, 1992). Average endosomal pH reached 6.20 +/- 0.07 (SE) after 15 min in the mock-transfected cells with a half time of approximately 3 min; pH was slightly lower (5.97 +/- 0.06) in the CFTR-expressing fibroblasts. The difference did not result from a subpopulation of highly acidic endosomes. Forskolin (10 microM) increased average pH to 6.62 +/- 0.03 and abolished the difference. For determination of Cl conductance, endosomes in fibroblasts and T84 cells were labeled with Cf-dextran (5 mg/ml); dissipation of the endosomal pH gradient was measured in response to rapid addition of the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP; 20 microM). Because the proton flux across the endosomal membrane is limited by the movement of K and Cl, the rate of alkalinization (dpH/dt) after CCCP addition provided a measure of endosomal Cl conductance. In CFTR-expressing fibroblasts, forskolin (10 microM) increased dpH/dt 1.6 +/- 0.2-fold (n = 14).(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence lifetime imaging microscopy (flimscopy). Methodology development and application to studies of endosome fusion in single cells

A new method of fluorescence microscopy for cell imaging has been developed that takes advantage of the spatial variations of fluorescence lifetimes in single cells as a source of image contrast, and thus it is named "fluorescence lifetime imaging microscopy (flimscopy)". Since time-resolved fluorescence measurements are sensitive to molecular dynamics and interactions, flimscopy allows the molecular information to be visualized in single cells. In flimscopy measurements, several (nanosecond) time-resolved fluorescence images of a sample are obtained at various delay times after pulsed laser excitation of the microscope's entire field of view. Lifetimes are calculated pixel-by-pixel from these time-resolved images, and the spatial variations of the lifetimes are then displayed in a pseudocolor format (flimscopy image). The total data acquisition time needed to obtain a flimscopy image with the diffraction-limited spatial resolution (approximately 250 nm) is decreased to just approximately 30 s for approximately 300 fluorescent molecules/micron2. This was achieved by developing a high-frequency (400 kHz) nanosecond-gating (9 ns full width at half height)-signal accumulation system. This technique allows the extent of resonance energy transfer to be visualized in single living cells, and is free from the errors due to variations in path length, light scattering, and the number of fluorophores that necessitate complex corrections in steady-state microfluorometry and fluorescence ratio imaging microscopy. Flimscopy was applied here to observe the extent of fusion of individual endosomes in single cells. Results revealed the occurrence of extensive fusion between primary endocytic vesicles and/or sorting endosomes, thereby raising the possibility that the biogenesis of sorting endosomes involves multiple fusions of primary endocytic vesicles.

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)

Development of a streak-camera-based time-resolved microscope fluorometer and its application to studies of membrane fusion in single cells

A time-resolved microscope fluorimeter based on a synchroscan streak camera and a fast pulsed laser system has been developed to measure the fluorescence lifetime decay under the fluorescence microscope. This system allows one to measure the nanosecond fluorescence lifetimes of fluorophores in a small spot (0.8-6.3 microns diameter) in single cultured cells under a fluorescence microscope, while the cells are being viewed under a high-power objective lens. A signal acquisition time between a second and a minute was usually sufficient to obtain fluorescence decay curves with good quality for 10(3)-10(5) fluorophores localized in 1 microns 2 domain. A signal-to-noise ratio better than 30 was obtained for approximately 30,000 fluorescein-labeled band 3 molecules in a 2 microns 2 region in a single human erythrocyte ghost after signal accumulation for 30 s. The measured lifetimes for a variety of fluorescent probes attached to proteins in solution and lipids in liposomes showed a good agreement with those measured in a cuvette under standard conditions by time-correlated single photon counting. With the development of this instrument, microscope fluorimetry has become a practical, straightforward, quantitative technique for investigation of molecular processes in single cells in culture. Time-resolved microscope fluorimetry has been applied to observe fusion of liposomes in vitro and that of endosomes in single cells by monitoring resonance energy transfer. Inspection of individual liposomes and endosomes revealed the extent of fusion for each vesicle. Since the use of time-resolved microscope fluorimetry eliminates the need for subcellular fractionation or the complex correction procedures in steady-state microfluorimetry, it greatly simplifies the assay for endosome fusion in vivo. The results showed that extensive fusion of sequentially formed endosomes takes place all over the cell matrix in cultured cells. This suggests that extensive fusion with incoming endosomes takes place in many endosomal compartments, possibly sorting organelles, or that the early endosomes fuse with the preexisting network of tubular cisternae of the endosomal compartment at many points in the network. It is concluded that time-resolved microscope fluorimetry is a powerful noninvasive technique for studies of in situ biochemistry and biophysics using cells and tissues.

Iterative fractionation of recycling receptors from lysosomally destined ligands in an early sorting endosome.

To study the fusion and separation of endocytic compartments, we have used digital image analysis to quantify the accumulation of fluorescent ligands in endosomes during continuous endocytosis for periods of 1-20 min. Fluorescently labeled transferrin (Tf) and low density lipoproteins (LDL) were used as markers of recycling receptors and lysosomally directed ligands respectively. By measuring the intensity of individual endosomes, we found that the amount of LDL per endosome increases 30-40-fold between 1 and 10 min and then plateaus. In contrast, the amount of Tf per endosome reaches a steady state within 2 min at a level that is only three to four times that at 1 min. We used pulse-chase double label methods to demonstrate that Tf cycles through the compartment in which the LDL accumulates. When both Tf and LDL are added to cells simultaneously for 2 min, nearly all endosomes contain both labels. With 2-4 min further incubation in the absence of external ligands, LDL-containing compartments become depleted of Tf as Tf is directed to para-Golgi recycling endosomes. However, if Tf is added to the medium 2-4 min after a pulse with LDL, most of the LDL-containing endosomes become labeled with Tf. The data indicate that at least 30-40 endocytic vesicles containing both Tf and LDL fuse with an endosomal compartment over a period of 5-10 min. LDL accumulates within this compartment and Tf is simultaneously removed. Simple mathematical models suggest that this type of iterative fractionation can lead to very high efficiency sorting.

Electron microscopic observations concerning the in vivo uptake and release of the agent of guinea-pig inclusion conjunctivitis ( Chlamydia psittaci) in guinea-pig exocervix

This report details electron-microscopical observations concerning C. psittaci infection in vivo. The model employed was that of the guinea-pig infected at the exocervical region with the agent of guinea-pig inclusion conjunctivitis (GPIC). Our observations indicate that chlamydial particles gain access to their target cells by the mechanism of endocytosis. Single GPIC elementary bodies were seen to be positioned within individual endosomes. The observations reported here provide evidence that chlamydial particles that had undergone their developmental cycle within the exocervical epithelial cells may leave the epithelium in 2 ways; within entire infected cells that had been shed into the lumen of the cervix and by means of the liberation of chlamydial particles from disrupted cells. The mechanism of cell disruption and shedding is thought to involve the large number of PMNs observed to be present within the enlarged intercellular spaces of the infected epithelium.