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Mapping of tetraspanin-enriched microdomains that can function as gateways for HIV-1
Correspondence to Markus Thali: markus.thali{at}uvm.edu
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Specific spatial arrangements of proteins and lipids are central to the coordination of many biological processes. Tetraspanins have been proposed to laterally organize cellular membranes via specific associations with each other and with distinct integrins. Here, we reveal the presence of tetraspanin-enriched microdomains (TEMs) containing the tetraspanins CD9, CD63, CD81, and CD82 at the plasma membrane. Fluorescence and immunoelectron microscopic analyses document that the surface of HeLa cells is covered by several hundred TEMs, each extending over a few hundred nanometers and containing predominantly two or more tetraspanins. Further, we reveal that the human immunodeficiency virus type 1 (HIV-1) Gag protein, which directs viral assembly and release, accumulates at surface TEMs together with the HIV-1 envelope glycoprotein. TSG101 and VPS28, components of the mammalian ESCRT1 (endosomal sorting complex required for transport), which is part of the cellular extravesiculation machinery critical for HIV-1 budding, are also recruited to cell surface TEMs upon virus expression, suggesting that HIV-1 egress can be gated through these newly mapped microdomains.
Abbreviations used in this paper: ESCRT, endosomal sorting complex required for transport; HIV-1, human immunodeficiency virus type 1; LE, late endosome; MVB, multivesicular body; TEM, tetraspanin-enriched microdomain; VLP, virus-like particle.
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250 amino acids) membrane proteins that contain cytoplasmic NH2 and COOH termini and two extracellular domains separated from each other by a short inner loop. The mammalian family of these evolutionarily conserved proteins contains 32 members. Tetraspanins are expressed in a wide range of tissues and cell types, and members of this protein family have been implicated in regulating various biological functions, including antigen presentation, cell adhesion and migration, cell–cell fusion, cell activation, and proliferation (for reviews see Berditchevski, 2001; Vogt et al., 2002; Hemler, 2003; Stipp et al., 2003; Tarrant et al., 2003; Hemler, 2005). Tetraspanins associate specifically with distinct integrins, various Ig superfamily members, and other tetraspanins, thus establishing a scaffold for various cellular functions. Numerous biochemical analyses and functional studies predicted the existence of tetraspanin-enriched microdomains (TEMs) that together form the so-called tetraspanin web (Charrin et al., 2003; Levy and Shoham, 2005). TEMs are thought to organize the plasma membrane and intracellular membranes, where some tetraspanins are primarily located, by selectively concentrating specific membrane proteins and membrane-peripheral signaling molecules. Such TEM-based concentration/exclusion of proteins involved, for example, in adhesion or in intracellular signaling is thought to dynamically segregate molecules, similar to how lipid rafts are proposed to laterally organize cellular membranes. Although some studies have documented colocalization of individual tetraspanins with various membrane receptors and costimulatory molecules, e.g., in adhesion complexes (Berditchevski et al., 1997; Berditchevski and Odintsova, 1999), the concept that different members of the tetraspanin family associate at membranes, thus forming distinct microdomains, is based largely on coimmunoprecipitation and protein cross-linking data. Neither the mean size of TEMs nor their overall distribution at the plasma membrane of these microdomains has been determined.
Human immunodeficiency virus type 1 (HIV-1), like other enveloped viruses, exits from cells by budding through membranes, a process that does not lead to disintegration of the cell. For its budding, HIV-1 uses the host cell machinery that is responsible for the formation of intralumenal vesicles in multivesicular bodies (MVBs), components of the endosomal compartment (for review see Morita and Sundquist, 2004). Nevertheless, HIV-1 primarily buds through the plasma membrane of T lymphocytes and other cell types. Only in macrophages is HIV-1 known to bud exclusively into MVBs. Viruses sequestered in these late endosomes (LEs) are thought to exit from macrophages upon fusion of the limiting membrane of MVBs with the plasma membrane (Raposo et al., 2002; Pelchen-Matthews et al., 2003).
HIV-1 produced in macrophages specifically incorporates the tetraspanin CD63, compatible with the finding that this antigen largely resides at the limiting membrane and on intralumenal vesicles of LEs/MVBs (Escola et al., 1998; Kobayashi et al., 2000; Gruenberg, 2001; Rous et al., 2002; Pelchen-Matthews et al., 2003). However, despite its low abundance at the plasma membrane of cells, CD63 is also specifically incorporated into HIV-1 particles produced in primary and transformed T lymphocytes and in other nonmacrophages where this virus buds mainly through the cell cortex (Orentas and Hildreth, 1993; Ott, 2002). Furthermore, we previously reported that we occasionally observed colocalization of HIV-1 Gag and CD63 at the periphery of T lymphocytes and melanocytes, though it was difficult to distinguish with certainty between the small fraction of CD63 associated with the plasma membrane and the vast majority of this antigen residing on intracellular membranes (Nydegger et al., 2003).
Here, we tested the hypothesis that the small fraction of CD63 that resides at the plasma membrane is concentrated at distinct microdomains, i.e., in TEMs, together with other members of the tetraspanin family. Fluorescence microscopy analysis of cells in which we selectively stained the surface fractions of tetraspanins combined with EM of immunolabeled sheets of plasma membrane allowed us to visualize TEMs containing the tetraspanins CD9, CD81, CD82, and CD63. Our data also document the size and distribution of these TEMs in membranes. Furthermore, the data presented in this paper suggest that these newly visualized plasma membrane microdomains can function as exit gateways for HIV-1.
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Next, cells were stained for the plasma membrane fraction of the selected tetraspanin, as described in Fig. 1 B, and the relative colocalization of surface CD63 with CD9, CD81, or CD82 was assessed. Substantial colocalization of CD63 with any one of the three tetraspanins was observed (Fig. S2, available at http://www.jcb.org/cgi/content/full/jcb.200508165/DC1), suggesting that relatively large fractions of CD9 and CD82 reside in plasma membrane TEMs together with CD63, whereas a small fraction of total CD63 contributes to these surface microdomains. The concept that various tetraspanins contribute dissimilarly to the formation of TEMs is based on biochemical studies only (for review see Hemler, 2003). The data presented in Fig. 2 and Fig. S2 support that concept and provide an unprecedented visualization of bona fide surface TEMs.
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Although biochemical analyses (i.e., coprecipitation experiments) allow determination of how much an individual tetraspanin contributes to an average TEM, such analyses of the bulk population do not permit determination of whether those relative contributions are uniform, i.e., whether tetraspanins accumulate at TEMs in defined ratios. The analysis of triple immunostainings, however, can provide such information. The magnifications in Fig. 2 (right) and Fig. 3 A visualize that the composition of TEMs at steady state varies widely, and the statistical analysis shown in Fig. 3 B documents that the tetraspanins analyzed in this study do not exist in TEMs in distinct, uniform ratios. Note that TEMs containing only one or two of the three analyzed tetraspanins were excluded from this quantification. TEM heterogeneity may thus be even larger than suggested by the graph shown in Fig. 3 B.
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TEM positioning relative to HA-enriched microdomains
A recent ultrastructural study analyzed the surface distribution in HAb2 fibroblasts of the influenza viral envelope glycoprotein HA. HA, a membrane protein that is sometimes used as marker for fluid-ordered raft domains, was demonstrated to cluster at distinct plasma membrane microdomains if expressed independently or together with the other viral proteins (Takeda et al., 2003; Hess et al., 2005). To investigate the spatial relationship between HA and the tetraspanins CD9 and CD63, HeLa cells expressing HA were surface stained with the respective antibodies. Fig. 5
(left) documents the 2D distribution of HA at the plasma membrane of these cells. As in HAb2 cells, HA is restricted to discrete microdomains of variable size. Although the overall appearance (size and distribution) of HA clusters resembles that of CD9- and CD63-containing TEMs (Fig. 5, middle), very little colocalization (<10%) was detected between HA and either CD9 or CD63 (right).
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Various biochemical and functional studies have linked specific cellular processes to the association of distinct proteins and tetraspanins. However, few studies have also analyzed the localization of tetraspanins involved in these processes, and physical aspects of TEMs, particularly size and distribution of these microdomains, have remained enigmatic. We hypothesized that CD63-enriched microdomains exist at the cell surface despite the fact that this tetraspanin is a resident primarily of LEs/MVBs. Fig. 1 documents for HeLa cells that this is indeed the case. These surface microdomains at first sight appear morphologically featureless; i.e., they are not restricted to pseudopods, for example, but they are distributed over the entire plasma membrane. The same holds for the other three tetraspanins analyzed in this study. Not only do they colocalize to a significant extent with CD63, surface TEMs containing these other tetraspanins are also spread over the entire cell surface and are not apparently engaged in any adhesion/migration-related functions (Fig. 2), though, as noted below, they clearly appear to be enriched in microvilli.
Size and 2D distribution of plasma membrane TEMs
To confirm the distribution pattern visualized by fluorescence microscopy and to get information about the size of surface TEMs, we used an immuno-EM technique that we had applied before and that allowed us to look perpendicularly with respect to the plane of the plasma membrane (Sanan and Anderson, 1991; Foti et al., 1997). Although the majority of the plasma membrane appeared devoid of CD63 and CD9, distinct clusters of these two antigens can be found dispersed over the entire cell surface. As integral membrane proteins, CD9 and CD63 arrive at the cell surface on vesicles that are inserted into the plasma membrane. The finding that all the TEMs analyzed in this study (Figs. 1–4
) are separated from each other by areas that are virtually free of these antigens suggests that the four tetraspanins, rather than diffusing in the 2D plane, stay clustered in small areas that cover only a relatively small fraction of the membrane. Even though TEMs are immediately recognizable as distinct microdomains, size, shape, and the relative presence of the four tetraspanins in these domains varies substantially, as is evident in Figs. 2–4 and 7. Whether the larger domains visualized here represent clusters of smaller base units or whether TEMs grow continuously until they reach a maximal size remains to be analyzed. Finally, though these domains appear uniformly distributed within the plasma membrane, our ultrastructural analysis of plasma membrane sheets (Figs. 4 and 7) reveals that TEMs form preferentially at or adjacent to clathrin-coated areas and next to elements of the cytoskeleton. The former feature clearly sets them apart from HA-enriched microdomains, which are situated in membrane areas free of clathrin-coated pits (Hess et al., 2005).
TEM biogenesis
Recent studies in rodent cells have suggested that CD63, upon synthesis, is sorted directly to LEs/MVBs, where most of this antigen resides (Rous et al., 2002; Ihrke et al., 2004), though some of the newly synthesized protein may be sorted via the plasma membrane. Fluorescence microscopy and ultrastructural analyses of secretory lysosomes and MVBs, respectively (Murk et al., 2003; Jaiswal et al., 2004), suggested that proteins are not uniformly distributed within the limiting membrane of these LEs/MVBs. Data presented in one of these studies (Jaiswal et al., 2004) are compatible with the possibility that CD63 is clustered within distinct microdomains of the limiting membrane. It would thus be conceivable that TEMs nucleate in the limiting membrane of endosomes/secretory lysosomes and become part of the plasma membrane after these compartments have moved to the cell surface and the limiting membrane has been inserted into the plasma membrane. Alternatively, significant fractions of newly synthesized LE/lysosomal markers lamp1, lamp2, and CD63 appear to be sorted via the plasma membrane before reaching their final destination in HeLa cells (Janvier and Bonifacino, 2005). Insertion of post-Golgi vesicles into the plasma membrane may thus contribute to the formation of surface TEMs.
TEMs roles in viral egress
Two lines of evidence in our current study suggest that surface TEMs can serve as exit gateways for HIV-1. First, most cell surface punctae where either Gag or Env clusters in both HeLa cell and in Jurkat T lymphocytes are also occupied by one of the tetraspanins (Figs. 6–8 and 10). Second, cellular TSG101 and VPS28, the components of the cellular budding machinery responsible for viral egress (Morita and Sundquist, 2004), when recruited to the plasma membrane in cells producing HIV-1, accumulate at CD63-containing TEMs (Fig. 8). Furthermore, we find that distortion of TEM distribution in virus-producing cells by an anti-CD9 antibody (K41) correlates with inhibition of HIV-1 release (unpublished data).
In a study where we used the FlAsH technique for successive dual-color labeling (Gaietta et al., 2002) of Gag in various virus-secreting cell types, we observed localization of newly synthesized Gag at distinct areas on the plasma membrane (Rudner et al., 2005). We also documented that viral budding structures and CD63 colocalize at MVBs and at the surface of HeLa cells (Nydegger et al., 2003). Based on this latter finding and on the relatively large size (1–4 µm) of patches at the plasma membrane through which the virus appeared to bud in this preceding, lower resolution study, we hypothesized that the microdomains through which HIV-1 buds are derivatives of LE/MVB limiting membrane (see above). However, the results presented in Figs. 6–8 indicate that the large patches observed in our previous studies may indeed have been clusters of smaller, possibly post-Golgi vesicle-derived TEMs that form supraclusters in cells producing virus (Figs. 6 and 8 and Fig. S3).
Although it is well documented that HIV-1 exit from cells is restricted to distinct areas of the cell cortex, it remained unclear which of the viral components is the primary determinant that targets release to these sites. A fluorescence microscopy analysis demonstrated that Gag recruits Env to distinct areas at the plasma membrane (Hermida-Matsumoto and Resh, 2000). Consistent with this paper, we show that Gag has intrinsic TEM targeting information as it colocalizes with TEMs if expressed alone (Fig. 9) and thus codetermines where HIV-1 buds. Nevertheless, Gag colocalizes more extensively with surface tetraspanins if Env is coexpressed (Figs. 6 and 9 and Fig. S5), and Env thus plays at least a modulatory role in determining where HIV-1 exits from cells.
Biochemical studies (Rousso et al., 2000; Lindwasser and Resh, 2001; Ono and Freed, 2001) and a fluorescence microscopy analysis in T lymphocytes, where HIV-1 was shown to exit at the same pole where the raft marker GM1 accumulates (Nguyen and Hildreth, 2000), suggested that lipid rafts or barges are critical for HIV-1 exit. On the other hand, it was also reported that Gag complexes, defined by flotation studies, do not incorporate classical lipid raft markers and were not disrupted by cholesterol extraction (Ding et al., 2003). Further, as reviewed recently elsewhere, rafts probably have many different properties, and these lipid-based microdomains remain difficult to define (Edidin, 2003; Mukherjee and Maxfield, 2004). Nevertheless, the two hypotheses, i.e., that rafts are important during HIV-1 assembly and that TEMs serve as viral exit gateways, are not mutually exclusive. Rafts, for example, could potentially form and/or coalesce during viral budding at TEMs. However, as recently noted (Yang et al., 2004), though tetraspanins are palmitoylated, a proteomics analysis of lipid rafts did not reveal any tetraspanins or integrins, nor were typical raft proteins found in a mass spectrometry analysis to be partners for tetraspanins and palmitoylated integrins (Foster et al., 2003; Yang et al., 2004). Also, HA-containing rafts (Hess et al., 2005) for the most part do not colocalize with TEMs containing CD9 and/or CD63 in HeLa cells, as documented in Fig. 5.
Although this study provides evidence for the concept that surface TEMs can serve as HIV-1 exit sites, we are currently investigating whether the viral components can also be endocytosed via these domains. The concept that viral components may be sequestered in the endosomal compartment to be mobilized for virion formation later, e.g., upon attachment to a target cell, was first discussed by Rodriguez-Boulan et al. (1983). The positioning of TEMs adjacent to clathrin-coated areas (Figs. 4 and 7), together with various reports about the itineraries of CD63 as well as HIV-1 Gag and Env (Blot et al., 2003; Lindwasser and Resh, 2004; Murray et al., 2005), are compatible with such a scenario.
In summary, data presented in this paper provide a map of surface TEMs and demonstrate that these domains constitute sites at which HIV-1 proteins gather for potential subsequent particle exit. TEMs have been implicated in coordinating functions at the cell–cell interface. It is thus conceivable that HIV-1 evolved to egress through these microdomains to ensure efficient release toward adjacent target cells.
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The following plasmids were used: pNL4-3, pGagopt (a gift from D. Ott, National Cancer Institute at Frederick, Frederick, MD), pSRalpha-Env, pVPS28-CFP, pTSG101-YFP (a gift from P. Bienasz, The Rockefeller University, New York, NY), pTSG101-GFP, pFLAG-VPS28 (a gift from U. von Schwedler and W. Sundquist, University of Utah, Salt Lake City, UT), pCD82-YFP (a gift from W. Mothes, Yale University School of Medicine, New Haven, CT), and pCD63-YFP (a gift from J. Bonafacino, National Institutes of Health, Bethesda, MD). Analysis of cells was performed 24 h after transfection with pGagopt or pSRalpha-Env alone or when cotransfected with pGagopt, pSRalpha-Env, pVPS28-CFP, pFLAG-VPS28, or pTSG101-GFP/YFP, and after 30–48 h when transfected with pNL4-3.
Immunocytochemistry and fixed cell imaging analysis by fluorescence microscopy
Adherent cells were plated in chambered coverglasses (Lab-Tek; Nunc) or in 35-mm glass-bottomed culture dishes (MatTek). Transfection and staining were performed directly in these chambers.
The following antibodies were used: anti-CD9 (K41; BMA Biomedicals AG); anti-CD63 (H5C6; Developmental Studies Hybridoma Bank); anti-CD63 clone 1B5 (a gift from J. Gruenberg [University of Geneva, Geneva, Switzerland] and M. Marsh [University College London, London, UK]); anti-CD81 (JS-81; BD Biosciences); anti-CD82 (B-L2; Diaclone); anti-Env (B12; NIH AIDS Research & Reference Reagent Program); anti-p6 (AIDS Vaccine Program, National Cancer Institute); anti-VPS28 serum; anti-HA rabbit serum (gift from M. Roth, The University of Texas Southwestern Medical Center, Dallas, TX); anti-mouse Alexa Fluor 488, 594, and 647; anti-rabbit Alexa Fluor 488, 594, and 647; and anti-human Alexa Fluor 488 and 594 (Invitrogen).
The slides were examined on a Delta Vision (DV) Workstation (DV base 3/3.5; epifluorescence microscope [Eclipse TE200; Nikon] fitted with an automated stage [Applied Precision, Inc.]) using a Plan Apo 60x objective (Nikon), 1.40 NA. Images were captured in z series with a charge-coupled device digital camera (CH350E or CoolSnap HQ [Roper Scientific]) using the DV Softworx software. Out-of-focus light was digitally removed using Softworx deconvolution software (Applied Precision Inc.), using the standard DV iterative deconvolution algorithm. Levels on each channel were adjusted in the DV Softworx software, and z sections of interest were exported as Tiff files. Tiffs were assembled into figures using Photoshop (Adobe).
Quantification of colocalization was computed using the Classifier Module of the Volocity Software 3.1 (Improvision). The bottom sections of representative cells were analyzed. Fluorescence thresholds for individual channels were set to two times the standard deviation of the signal, and the fluorescence intensity of each pixel was measured. Colocalization percentages were calculated by dividing the total number of pixels with intensity above the threshold that overlapped between two channels by the total number of pixels with intensity above the threshold for a given channel.
The relative contributions of tetraspanins to the formation of TEMs was assessed by selecting fluorescence thresholds for each channel followed by counting the individual clusters of each tetraspanin to gauge the presence or absence of one, two, or all three channels in a given cluster. The relative contributions of tetraspanins to the formation of triple TEMs (Fig. 3) was calculated by selecting TEMs containing signal for three tetraspanins and quantifying the relative intensity and area of each channel in a given TEM.
Overall staining
Cells were washed with PBS and fixed with 3.7% paraformaldehyde (Electron Microscopy Sciences) for 10 min at room temperature. After washing with PBS, cells were permeabilized with 0.2% Triton X-100 in PBS for 10 min, washed again, and blocked with 1% BSA in PBS for 10 min, followed by a 1-h incubation with primary antibody at 37°C. After extensive washing with PBS, cells were blocked again with 1% BSA in PBS for 10 min and then incubated with the appropriate fluorophore-conjugated secondary antibody for 30 min. After extensive washing with PBS, cells were overlaid with 1% BSA in PBS and examined by fluorescence microscopy.
In case multiple antibodies of the same species were used, the antibodies were conjugated with a fluorophore using the Zenon technology according to the manufacturer's protocol (Invitrogen) before incubation with cells. Also, we routinely incubate cells with no, or only one (in dual stainings) or two (in triple stainings), primary antibodies, to control for nonspecific binding of the secondary antibodies.
Surface staining
Cells were washed with PBS and fixed with 3.7% paraformaldehyde for 10 min. Without permeabilization, cells were incubated for 1 h with primary antibody at 37°C in 1% BSA in PBS. Alternatively, live cells were precooled on ice and incubated for 1 h on ice at 4°C with primary antibody in complete medium supplemented with 1% Ca2+. Cells were then washed extensively with PBS and fixed for 10 min with 3.7% paraformaldehyde. After washing with PBS, cells were blocked for 10 min with 1% BSA in PBS and incubated with the appropriate fluorophore-conjugated secondary antibody for 30 min at room temperature. After extensive washing with PBS, cells were overlaid with 1% BSA in PBS and examined by fluorescence microscopy.
If two different surface stainings were performed on the same cells, both primary antibodies were added at the same time, followed by fluorophore-conjugated secondary antibody incubation. In case surface staining was followed by an overall staining, cells were permeabilized subsequently and treated with primary antibody followed by fluorophore-conjugated secondary antibody as described above.
Surface staining of Jurkat T lymphocytes
Jurkat cells were washed with PBS and incubated in suspension for 1 h on ice at 4°C with primary antibody in complete medium supplemented with 1% Ca2+. The cells were then washed with PBS and fixed with 3.7% paraformaldehyde for 10 min. The cells were washed, blocked for 10 min in 1% BSA in PBS, and transferred to chambered coverglasses precoated with CellTak (BD Biosciences) and incubated with the secondary antibodies at 37°C, simultaneously immobilizing the cells on the coverglass. In case multiple antibodies of the same species were used, the antibodies were conjugated with a fluorophore using the Zenon technology, and the stainings were done in series.
EM analysis
CD63- or CD9-enriched microdomains were visualized at the EM ultrastructural level on the inner face of the plasma membrane of HeLa cells as previously described (Sanan and Anderson, 1991; Foti et al., 1997). In brief, HeLa cells were incubated for 1 h at 4°C with either anti-CD63 antibodies (clone 1B5 of mouse anti-CD63 IgG2b [Fraile-Ramos et al., 2001] and antibody H5C6) or anti-CD9 antibodies (clone KMC8.8 of rat anti-CD9 [Santa Cruz Biotechnotolgy, Inc.] or K41 [Bachem]) in cold 1% BSA in PBS. After antibody binding, cells were washed twice in cold PBS to remove excess antibody and incubated with secondary species-specific gold-conjugated antibodies (10- or 20-nm colloidal gold) for 1 h at 4°C. Unbound secondary antibody was removed by washing twice with cold PBS. Cells were detached from the Petri dishes and allowed to sediment on formvar-coated EM nickel grids previously coated with poly-L-lysine. Adherent isolated plasma membranes were obtained by incubating the cells attached to the grids with hypotonic (0.65x) PBS for 30 s and then sonicating the cells at a weak power. This procedure disrupts the cells but allows a large portion of plasma membranes with conserved internal structures, such as clathrin-coated membranes and cytoskeleton elements, to stay adherent to the poly-L-lysine–coated grids. Adherent membranes were next washed with cold PBS and prefixed for 15 min at 4°C with 1% N- (3-dimethylaminopropyl)-N'-ethylcarbodiimide hydrochloride/0.2% glutaraldehyde, followed by 15 min at room temperature with 4% glutaraldehyde in PBS. Adherent membranes were subsequently fixed in 2% osmium tetroxide in PBS for 8 min and 30 s at room temperature, washed three times for 5 min with PBS, incubated with 1% aqueous tannic acid for 10 min, washed twice for 5 min in distilled water, incubated with 1% uranyl acetate for 10 min, and washed twice for 1 min with distilled water before air-drying. For CD63–CD9 double-labeling experiments, CD63 gold labeling was performed as described above, but CD9 was localized using a rabbit polyclonal anti-CD9 antibody (clone H-110; Santa Cruz Biotechnology, Inc.). Membranes considered well conserved were then photographed on an electron microscope (CM10; Philips). The mean size of CD63-enriched microdomains, as well as the mean distance separating these domains, was determined by analyzing 23 EM micrographs illustrating >50 well-delimited CD63-enriched microdomains. For this analysis, a grid consisting of squares with 200-nm length was positioned onto the images, and the numbers of gold particles per square were evaluated. Adjacent squares containing a sum of at least five particles were considered one TEM, and the mean size of these domains was calculated. The mean distance between TEMs was calculated by measuring the distances between the outermost squares defining the individual TEMs. To quantify either colocalization of CD63 and CD9 (Fig. 4) or Gag and tetraspanins (Fig. 7), the numbers of tetraspanin-associated gold particles situated either within the same square or in adjacent squares were determined (Fig. 4), or the numbers of Gag-associated gold particles overlapping with or directly adjacent to TEMs (as defined above) were determined. The percentages ± SEM are listed in the Results section.
For immunogold labeling of ultrathin cryosections, cells were detached and fixed for 1 h in phosphate buffer (100 mM NaPO4, pH 7.4) containing 4% paraformaldehyde (EMS) and 0.1% glutaraldehyde (EMS). Thereafter, the fixative was rinsed out three times with phosphate buffer and the cells were processed for cryosectioning as described previously (Liou et al., 1996). In brief, the cell pellet was infiltrated with sucrose and frozen in liquid nitrogen. Frozen sections (45-nm thickness) were cut with a cryotome (FCS; Leica), transferred to grids, and incubated with antibodies against CD63 (clone 1B5 of mouse anti-CD63 IgG2b). Grids were examined with a transmission electron microscope (Tecnai G-12; FEI Company).
Online supplemental material
Fig. S1 shows the overall distribution of the tetraspanins CD9, CD81, CD82, and CD63 when the cells were stained for only one of the antigens or dual labeled for two tetraspanins. Fig. S2 identifies surface TEMs containing two tetraspanins. Fig. S3 documents accumulation of viral Gag at plasma membrane TEMs containing CD9, CD81, or CD82. Fig. S4 demonstrates that TSG101 and VPS28, rather than accumulating at surface TEMs, are concentrated at intracellular compartments throughout the cell in the absence of viral Gag expression. Fig. S5 provides an immunofluorescence analysis of viral Env and Gag colocalization with tetraspanins representative of some of the data shown in Fig. 9. Video 1 shows untransfected HeLa cells that were surface stained for CD63, as described in Fig. 1. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200508165/DC1.
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Acknowledgments |
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This work was supported by National Institutes of Health grants R01 AI 47727 and R03 AI 060679 to M. Thali and Swiss National Science Foundation grant 3100A0-104489/1 to M. Foti.
Note added in proof. A recent article (Booth, A.M., Y. Fang, J.K. Fallon, J.-M. Yang, J.E.K. Hildreth, and S.J. Gould. 2006. J Cell Biol. 172:923–935) showed data compatible with the hypothesis that HIV-1 can exit through TEMs.
Submitted: 25 August 2005
Accepted: 1 May 2006
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