Jan W. Slot

Intracellular site of asialoglycoprotein receptor-ligand uncoupling: Double-label immunoelectron microscopy during receptor-mediated endocytosis

In rats infused with asialoglycoprotein for 60 min, receptor-mediated endocytosis of the ligand occurred exclusively in hepatic parenchymal cells. We have used double-label immunoelectron microscopy on ultrathin cryosections of rat liver to identify the site at which the asialoglycoprotein receptor and its ligand dissociate following their common endocytosis. Asialoglycoprotein receptor, ligand and clathrin were identified and quantitated by the use of monospecific antibodies followed by gold-protein A complexes. Both receptor and ligand were found associated with the membrane of clathrin-coated vesicles close to the cell surface. We identified other vesicles that contained ligand accumulated within the lumen. The membranes of these latter vesicles contained little receptor, but receptor was concentrated in tubular extensions that were largely free of ligand. We call this organelle CURL (compartment of uncoupling of receptor and ligand). CURL vesicles appear to transform into secondary lysosomes, wherein the ligand is degraded. The tubular vesicles are, we propose, an intermediate in recycling the receptor to the cell surface.

Improving structural integrity of cryosections for immunogold labeling.

Cryosections of aldehyde-fixed material prepared according to Tokuyasu are a good substrate for immunocytochemistry. However, structural defects occur that limit the resolution of this approach. We found that the step during which sections are thawed and transferred from the cryochamber to the supporting film on an EM grid is most critical for structural preservation. Surface tension of the transfer medium, on which sections are spread during thawing, can easily damage their structure by overstretching. By substituting a mixture of methylcellulose and sucrose for the conventional sucrose transfer medium, we were able to alleviate the problem of overstretching, thus improving greatly the structural integrity of thin cryosections. Also, material extraction from the sections after thawing causes structural damage, particularly when cross-linking is deficient. Incorporation of uranyl acetate in the transfer medium can then further help to maintain the structural integrity of the sections during the immunolabeling procedure. Excellent ultrastructure was featured in sections picked up and dried directly in methylcellulose/uranyl acetate mixtures. Such preparations can provide new insight into subcellular details and is an efficient back-up for immunolabeled sections in respect of their morphology. Cryosections from fresh frozen tissue can be preserved for immunolabeling by using transfer media that contain fixatives. This approach may have advantages if chemical fixation of tissue is thought to induce morphological artifacts or antigen redistribution.

Intracellular receptor sorting during endocytosis: Comparative immunoelectron microscopy of multiple receptors in rat liver

Using double-label quantitative immunoelectron microscopy on ultrathin cryosections of rat liver, we have compared the endocytotic pathways of the receptors for asialoglycoprotein (ASGP-R), mannose-6-phosphate ligands (MP-R), and polymeric IgA (IgA-R). All three were found within the Golgi complex, along the entire plasma membrane, in coated pits and vesicles, and within a compartment of uncoupling of receptors and ligand ( CURL ). The receptors occurred randomly at the cell surface, in coated pits and vesicles. Within CURL tubules ASGP-R and MP-R were colocalized , but IgA-R and ASGP-R displayed dramatic microheterogeneity. Thus, in addition to its role in uncoupling and sorting recycling receptor from ligand, CURL serves as a compartment to segregate recycling receptor (e.g. ASGP-R) from receptor involved in transcytosis (e.g. IgA-R).

Vesicular Tubular Clusters between the ER and Golgi Mediate Concentration of Soluble Secretory Proteins by Exclusion from COPI-Coated Vesicles

We have determined the concentrations of the secretory proteins amylase and chymotrypsinogen and the membrane proteins KDELr and rBet1 in COPII- and COPI-coated pre-Golgi compartments of pancreatic cells by quantitative immunoelectron microscopy. COPII was confined to ER membrane buds and adjacent vesicles. COPI occurred on vesicular tubular clusters (VTCs), Golgi cisternae, the trans-Golgi network, and immature secretory granules. Both secretory proteins exhibited a first, significant concentration step in noncoated segments of VTC tubules and were excluded from COPI-coated tips. By contrast, KDELr and rBet1 showed a first, significant concentration in COPII-coated ER buds and vesicles and were prominently present in COPI-coated tips of VTC tubules. These data suggest an important role of VTCs in soluble cargo concentration by exclusion from COPI-coated domains.

Cryosectioning and immunolabeling

In this protocol, we describe cryoimmunolabeling methods for the subcellular localization of proteins and certain lipids. The methods start with chemical fixation of cells and tissue in formaldehyde (FA) and/or glutaraldehyde (GA), sometimes supplemented with acrolein. Cell and tissue blocks are then immersed in 2.3 M sucrose before freezing in liquid nitrogen. Thin cryosections, cut in an ultracryotome, can be single- or multiple immunolabeled with differently sized gold particles, contrasted and viewed in an electron microscope. Semi-thin cryosections can be used for immunofluorescence microscopy. We describe the detailed procedures that have been developed and tested in practice in our laboratory during the past decades.

Liposome-encapsulated antigens are processed in lysosomes, recycled, and presented to T cells

Antigen processing requires intracellular antigen catabolism to generate immunogenic peptides that bind to class II MHC molecules (MHC-II) for presentation to T-cells. We now provide direct evidence that these peptides are produced within dense lysosomes, as opposed to earlier endocytic compartments. The protein antigen hen egg lysozyme was targeted to endosomes or lysosomes by encapsulating it in liposomes of different membrane composition. Acid-sensitive liposomes released their contents in early endosomes, whereas acid-resistant liposomes sequestered their contents from potential endosomal processing events and released their contents only after delivery to lysosomes. Antigen encapsulated in acid-resistant liposomes was processed in a chloroquine-sensitive manner and presented more efficiently than soluble antigen or antigen encapsulated in acid-sensitive liposomes. Thus, peptides may be recycled from lysosomes, transported to endosomes to bind MHC-II, and then expressed at the cell surface.

Selective binding of perfringolysin O derivative to cholesterol-rich membrane microdomains (rafts)

There is increasing evidence that sphingolipid- and cholesterol-rich microdomains (rafts) exist in the plasma membrane. Specific proteins assemble in these membrane domains and play a role in signal transduction and many other cellular events. Cholesterol depletion causes disassembly of the raft-associated proteins, suggesting an essential role of cholesterol in the structural maintenance and function of rafts. However, no tool has been available for the detection and monitoring of raft cholesterol in living cells. Here we show that a protease-nicked and biotinylated derivative (BCθ) of perfringolysin O (θ-toxin) binds selectively to cholesterol-rich microdomains of intact cells, the domains that fulfill the criteria of rafts. We fractionated the homogenates of nontreated and Triton X-100-treated platelets after incubation with BCθ on a sucrose gradient. BCθ was predominantly localized in the floating low-density fractions (FLDF) where cholesterol, sphingomyelin, and Src family kinases are enriched. Immunoelectron microscopy demonstrated that BCθ binds to a subpopulation of vesicles in FLDF. Depletion of 35% cholesterol from platelets with cyclodextrin, which accompanied 76% reduction in cholesterol from FLDF, almost completely abolished BCθ binding to FLDF. The staining patterns of BCθ and filipin in human epidermoid carcinoma A431 cells with and without cholesterol depletion suggest that BCθ binds to specific membrane domains on the cell surface, whereas filipin binding is indiscriminate to cell cholesterol. Furthermore, BCθ binding does not cause any damage to cell membranes, indicating that BCθ is a useful probe for the detection of membrane rafts in living cells.

Immunoelectron Microscopic Localization of Cholesterol Using Biotinylated and Non-cytolytic Perfringolysin O:

We used a proteolytically modified and biotinylated derivative of the cholesterol-binding θ-toxin (perfringolysin O) to localize cholesterol-rich membranes in cryosections of cultured human lymphoblastoid cells (RN) by electron microscopy. We developed a fixation and immunolabeling procedure to improve the preservation of membranes and minimize the extraction and dislocalization of cholesterol on thin sections. We also labeled the surface of living cells and applied high-pressure freezing and subsequent fixation of cryosections during thawing. Cholesterol labeling was found at the plasma membrane, with strongest labeling on filopodium-like processes. Strong labeling was also associated with internal vesicles of multivesicular bodies (MVBs) and similar vesicles at the cell surface after secretion (exosomes). Tubulovesicular elements in close vicinity of endosomes and the Golgi complex were often positive as well, but the surrounding membrane of MVBs and the Golgi cisternae appeared mostly negative. Treatment of cells with methyl-β-cyclodextrin completely abolished the labeling for cholesterol. Our results show that the θ-toxin derivative, when used in combination with improved fixation and high-pressure freezing, represents a useful tool for the localization of membrane cholesterol in ultrathin cryosections.

Peri-Golgi vesicles contain retrograde but not anterograde proteins consistent with the cisternal progression model of intra-Golgi transport

A cisternal progression mode of intra-Golgi transport requires that Golgi resident proteins recycle by peri-Golgi vesicles, whereas the alternative model of vesicular transport predicts anterograde cargo proteins to be present in such vesicles. We have used quantitative immuno-EM on NRK cells to distinguish peri-Golgi vesicles from other vesicles in the Golgi region. We found significant levels of the Golgi resident enzyme mannosidase II and the transport machinery proteins giantin, KDEL-receptor, and rBet1 in coatomer protein I–coated cisternal rims and peri-Golgi vesicles. By contrast, when cells expressed vesicular stomatitis virus protein G this anterograde marker was largely absent from the peri-Golgi vesicles. These data suggest a role of peri-Golgi vesicles in recycling of Golgi residents, rather than an important role in anterograde transport.

Immuno-electron tomography of ER exit sites reveals the existence of free COPII-coated transport carriers

Transport from the endoplasmic reticulum (ER) to the Golgi complex requires assembly of the COPII coat complex at ER exit sites. Recent studies have raised the question as to whether in mammalian cells COPII coats give rise to COPII-coated transport vesicles or instead form ER sub-domains that collect proteins for transport via non-coated carriers. To establish whether COPII-coated vesicles do exist in vivo, we developed approaches to combine quantitative immunogold labelling (to identify COPII) and three-dimensional electron tomography (to reconstruct entire membrane structures). In tomograms of both chemically fixed and high-pressure-frozen HepG2 cells, immuno-labelled COPII was found on ER-associated buds as well as on free ∼50-nm diameter vesicles. In addition, we identified a novel type of COPII-coated structure that consists of partially COPII-coated, 150–200-nm long, dumb-bell-shaped tubules. Both COPII-coated carriers also contain the SNARE protein Sec22b, which is necessary for downstream fusion events. Our studies unambiguously establish the existence of free, bona fide COPII-coated transport carriers at the ER–Golgi interface, suggesting that assembly of COPII coats in vivo can result in vesicle formation.