Your search keyword '"Endosomes classification"' showing total 5 results

1. Characterization of exosome subpopulations from RBL-2H3 cells using fluorescent lipids.

Author

Laulagnier K, Vincent-Schneider H, Hamdi S, Subra C, Lankar D, and Record M

Subjects

Animals, Antigens, CD analysis, Biological Transport, Cell Line, Tumor, Endosomes classification, Exocytosis, Fluorescent Dyes, Golgi Apparatus chemistry, Golgi Apparatus ultrastructure, Histocompatibility Antigens Class II analysis, Intracellular Membranes chemistry, Intracellular Membranes metabolism, Membrane Proteins analysis, Neuropeptides analysis, Platelet Membrane Glycoproteins, Rats, Tetraspanin 28, Tetraspanin 30, Endosomes chemistry, Lipids analysis

Abstract

Fluorescent lipid probes were used to track lipid trafficking between parent RBL cells and exosomes. We have checked the intracellular labeling of exosomes ("in vivo labeling") from parent cell incubated with either Bodipy-Cer, Bodipy-PC, or NBD-PC. Bodipy-PC labeled equally cells and exosomes, whereas Bodipy-Cer, a Golgi marker, was enriched in exosomes. Golgi membranes participated effectively in exosome biogenesis since cell incubation with brefeldin A leads to a modified phospholipid/protein ratio in exosomes. At the opposite, NBD-PC, a plasma membrane marker weakly labeled exosome membranes. Sorting of subpopulations indicated that the MHC-II containing exosomes were enriched in Bodipy-PC, whereas tetraspanin(CD 63 or CD81)-containing exosomes are essentially labeled with Bodipy-Cer and Bodipy-PC. These results indicated that RBL released two main subpopulations of exosomes that can be discriminated by their protein and lipid contents. When the bulk of exosomes was labeled after their purification ("in vitro labeling") with either of the above-mentioned lipid probes, the Bodipy-Cer was the only one to incorporate noticeably in all the subpopulations, indicating that the previous results obtained during "in vivo labeling" monitored real intracellular lipid trafficking between organelles and exosomes. Bodipy-Cer was further used as a tool to measure the respective amounts of each subpopulations. CD63, MHC II, and CD81-containing exosomes accounted for 47%, 32%, and 21%, respectively, of total exosomes.

Published

2005

2. Evolving endosomes: how many varieties and why?

Author

Perret E, Lakkaraju A, Deborde S, Schreiner R, and Rodriguez-Boulan E

Subjects

Animals, Cytoskeleton metabolism, Membrane Lipids metabolism, Protein Transport, Endosomes classification, Endosomes metabolism

Abstract

The cell biologist's insight into endosomal diversity, in terms of both form and function, has increased dramatically in the past few years. This understanding has been promoted by the availability of powerful new techniques that allow imaging of both cargo and machinery in the endocytic process in real time, and by our ability to inhibit components of this machinery by RNA interference. The emerging picture from these studies is of a highly complex, dynamic and adaptable endosomal system that interacts at various points with the secretory system of the cell.

Published

2005

3. The receptor recycling pathway contains two distinct populations of early endosomes with different sorting functions.

Author

Sheff DR, Daro EA, Hull M, and Mellman I

Subjects

Aluminum Compounds pharmacology, Animals, Cell Line, Cell Polarity, Centrifugation, Density Gradient, Dogs, Endosomes classification, Epithelial Cells cytology, Epithelial Cells metabolism, Fluorides pharmacology, GTP-Binding Proteins metabolism, Immunoglobulin A metabolism, Kidney, Kinetics, Models, Biological, Receptors, Polymeric Immunoglobulin metabolism, Receptors, Transferrin metabolism, rab4 GTP-Binding Proteins, Endocytosis physiology, Endosomes physiology, Receptors, Cell Surface metabolism, rab GTP-Binding Proteins

Abstract

Receptor recycling involves two endosome populations, peripheral early endosomes and perinuclear recycling endosomes. In polarized epithelial cells, either or both populations must be able to sort apical from basolateral proteins, returning each to its appropriate plasma membrane domain. However, neither the roles of early versus recycling endosomes in polarity nor their relationship to each other has been quantitatively evaluated. Using a combined morphological, biochemical, and kinetic approach, we found these two endosome populations to represent physically and functionally distinct compartments. Early and recycling endosomes were resolved on Optiprep gradients and shown to be differentially associated with rab4, rab11, and transferrin receptor; rab4 was enriched on early endosomes and at least partially depleted from recycling endosomes, with the opposite being true for rab11 and transferrin receptor. The two populations were also pharmacologically distinct, with AlF4 selectively blocking export of transferrin receptor from recycling endosomes to the basolateral plasma membrane. We applied these observations to a detailed kinetic analysis of transferrin and dimeric IgA recycling and transcytosis. The data from these experiments permitted the construction of a testable, mathematical model which enabled a dissection of the roles of early and recycling endosomes in polarized receptor transport. Contrary to expectations, the majority (>65%) of recycling to the basolateral surface is likely to occur from early endosomes, but with relatively little sorting of apical from basolateral proteins. Instead, more complete segregation of basolateral receptors from receptors intended for transcytosis occurred upon delivery to recycling endosomes.

Published

1999

4. Two distinct kinds of tubular organelles involved in the rapid recycling and slow processing of endocytosed transferrin.

Author

Sakai T, Mizuno T, Miyamoto H, and Kawasaki K

Subjects

Biological Transport, Endosomes classification, Endosomes ultrastructure, Epidermal Growth Factor metabolism, Fluorescent Dyes, Humans, Image Processing, Computer-Assisted, Lasers, Microscopy, Confocal, Transferrin analogs & derivatives, Tumor Cells, Cultured, Endocytosis, Endosomes metabolism, Transferrin metabolism

Abstract

The tubular structures of endosomes are thought to mediate the sorting and recycling of endocytosed macromolecules. These structures have been reported to show considerable morphological variety. However, it is not clear whether they are functionally identical. To address this question, we applied quantitative imaging analysis to characterize tubular organelles loaded with a recycling protein marker, fluorescent transferrin, in living human carcinoma HEp2 cells, using laser scanning confocal microscopy. High-resolution images of the cells demonstrated two types of tubular structures with a distinct morphology and showing a time dependency in their appearance: the fine tubular element and the extensive tubular element. Fine tubular elements 2-10 microns long were distributed throughout the cytoplasm after 10 min of loading with the tracer. Extensive tubular elements 5-20 microns long radiated from the cytocenter after 2 h of loading, but not after 10 min. Time-lapse imaging analysis demonstrated that the half-life of transferrin in the fine and extensive tubular elements was 12 min and approximately 50 min, respectively, at 33 degrees C. Double labeling experiments using fluorescent transferrin and epidermal growth factor indicated that the extensive tubular element was neither a late endosome nor a lysosome. From these results, we conclude that the fine tubular and extensive tubular elements are distinct organelles: the former comprising the sorting endosome and recycling compartment which mediate the rapid recycling of transferrin, and the latter being part of a novel pathway of slower transferrin processing.

Published

1998

5. A novel class of clathrin-coated vesicles budding from endosomes.

Author

Stoorvogel W, Oorschot V, and Geuze HJ

Subjects

Adaptor Protein Complex gamma Subunits, Biological Transport, Cell Membrane physiology, Cell Membrane Permeability, Cells, Cultured, Endosomes ultrastructure, Golgi Apparatus physiology, Histocytochemistry, Horseradish Peroxidase, Intracellular Membranes ultrastructure, Membrane Proteins isolation & purification, Clathrin isolation & purification, Endocytosis physiology, Endosomes classification, Intracellular Membranes classification, Receptors, Transferrin isolation & purification

Abstract

Clathrin-coated vesicles transport selective integral membrane proteins from the plasma membrane to endosomes and from the TGN to endosomes. Recycling of proteins from endosomes to the plasma membrane occurs via unidentified vesicles. To study this pathway, we used a novel technique that allows for the immunoelectron microscopic examination of transferrin receptor-containing endosomes in nonsectioned cells. Endosomes were identified as separate discontinuous tubular-vesicular entities. Each endosome was decorated, mainly on the tubules, with many clathrin-coated buds. Endosome-associated clathrin-coated buds were discerned from plasma membrane-derived clathrin-coated vesicles by three criteria: size (60 nm and 100 nm, respectively), continuity with endosomes, and the lack of labeling for alpha-adaptin. They were also distinguished from TGN-derived clathrin-coated vesicles by their location at the periphery of the cell, size, and the lack of labeling for gamma-adaptin. In the presence of brefeldin A, a large continuous endosomal network was formed. Transferrin receptor recycling as well as the formation of clathrin-coated pits at endosomes was inhibited in the presence of brefeldin A. Together with the localization of transferrin receptors at endosome-associated buds, this indicates that a novel class of clathrin-coated vesicles serves an exit pathway from endosomes. The target organelles for endosome-derived clathrin-coated vesicles remain, however, to be identified.

Published

1996