INTRODUCTION

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The envelope glycoproteins of retroviruses perform critical functions during virus entry and are the main targets of the humoral and cellular immune responses (16). They are synthesized in the rough endoplasmic reticulum of infected cells as precursors. The precursor is then processed during its passage along the exocytic pathway to yield the surface subunit (SU) and the transmembrane subunit (TM). These are then incorporated into budding virions. The SU is responsible for binding to receptors, and the TM anchors the envelope proteins at the membrane and induces membrane fusion during viral entry. The TM is composed of an ectodomain, a single membrane-spanning domain, and a C-terminal cytoplasmic domain (TM-CD). The TM-CD proteins of primate lentiviruses such as human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIV) are longer than those of most other retroviruses; they contain more than 150 amino acids, whereas the TM-CD proteins of other retroviruses are only 20 to 50 amino acids long (16).

The TM-CD of HIV-1 and SIV can affect the conformation of the glycoprotein ectodomain (40), the ability of the envelope to induce cell-to-cell fusion (34, 40), and the budding site in polarized epithelial cells (23, 24). Interactions between the TM-CD and virion structural proteins may influence the incorporation of the envelope protein during viral assembly (7, 10, 14, 43) and consequently the infectivity of virus particles (14, 15, 18, 30, 43). The membrane-proximal regions of most retroviral TM-CDs have a YXXØ Tyr-based motif (Y, Tyr; X, any amino acid; Ø, amino acid with a bulky hydrophobic side chain [Leu, Ile, Phe, Val, or Met]), reminiscent of the Tyr-containing internalization signals found in some cell surface proteins that undergo rapid endocytosis in clathrin-coated pits (9). Substitution of the tyrosine residue in this motif in the HIV-1 and SIV TM results in reduced rates of endocytosis, greater envelope expression on the surface of infected cells (19, 20, 36, 37), and perturbation of the polarized release of virions from epithelial cells (23). This latter effect also occurs for human T-leukemia virus type 1 (HTLV-1) (22). The sorting and trafficking of envelope glycoproteins is critical for the establishment of persistent viral infection in vivo. Sufficient envelope protein expression at the cell surface of infected cells ensures optimal incorporation into budding virions, but this amount must be tightly controlled to favor viral persistence by limiting exposure of this protein to the cellular and humoral immune responses.

YXXØ Tyr-based sorting signals can mediate the internalization of receptors from the cell surface and targeting to intracellular compartments, such as endosomes and lysosomes, via clathrin-coated pits associated with the AP-2 adaptor complexes at the plasma membrane or with the AP-1 complexes at the trans-Golgi network (9, 25). The medium chains µ2 and µ1 of the AP-2 and AP-1 clathrin-associated adaptor complexes can interact directly with the Tyr-based sorting signals found in the cytoplasmic domains of many transmembrane proteins and may serve as the recognition components of clathrin-coated pits (28). The other components of the adaptor complexes are the -, 2-, and 2-adaptins for AP-2 and the -, 1-, and 1-adaptins for AP-1 (31, 35). The AP-3 adaptor complex, which contains the medium chain µ3A, has recently been identified (12, 39). Interactions of the clathrin-associated adaptor complexes with the TM-CDs of retroviral envelope proteins, and the consequences of these interactions for envelope trafficking and virus function, are not fully elucidated. Ohno et al. used two-hybrid assays to show that the YXXØ motif of the HIV-1 TM-CD can bind to the isolated µ1 or µ2 subunit (29), and Boge et al. have recently reported interactions between the full-length retroviral HIV-1 TM-CD with isolated µ2 subunit and the AP-2 adaptor complexes (6).

This work investigates the involvement of the cytoplasmic domains of HIV-1, SIV, and HTLV-1 TM glycoproteins in the expression of envelope glycoprotein at the cell surface. We show that the membrane-proximal Tyr-based signal of HIV-1, SIV, and HTLV-1 TM-CDs is implicated in expression of envelope glycoprotein at the cell surface and in the binding to isolated µ chains of AP-1 and AP-2 adaptor complexes. We also find that all three retroviral TM-CDs bind to the whole AP complexes and that the full-length HIV-1 and SIV long TM-CDs can bind to 2 adaptin. This findings, together with studies with mutated Tyr-based motifs, indicate that determinants of the HIV-1 and SIV TM-CDs other than the canonical tyrosine motifs take part in the recruitment of the AP-1 and AP-2 complexes and in the expression of envelope glycoproteins at the cell surface.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Generation and transfection of CD8-TM-CD chimeras. DNA fragments encoding the full-length TM-CDs of HIV-1 LAI Env (amino acid residues 707 to 856), SIVmac239 Env (residues 716 to 879), and HTLV-1 Env (residues 465 to 488) or the membrane-proximal Tyr-based motifs of the TM-CDs of HIV-1 LAI (amino acid residues 707 to 726) and SIVmac239 (residues 716 to 733) were obtained by PCR and cloned in frame with the extracellular and transmembrane domains of human CD8 alpha chain (residues 1 to 211) into the pJ.CN vector (38) to generate the constructs pCD8-HIV, pCD8-SIV, pCD8-HTLV, pCD8-HIV, and pCD8-SIV. Point mutations of the essential tyrosine residue of the Tyr-based motifs were constructed by PCR-directed mutagenesis using appropriate primers. HIV-1 LAI Env Tyr 712 and SIVmac239 Env Tyr 721 (both with a TAT codon) were mutated to an alanine residue (GCT codon) (pCD8-HIV-Y712A, pCD8-HIV-Y712A, pCD8-SIV-Y721A, and pCD8-SIV-Y721A), the HTLV-1 Env Tyr 476 (TAC codon) was changed to a Ser (TCC) (pCD8-HTLV-Y476S), and HTLV-1 Env Tyr 479 (TAC codon) was replaced by a serine (TCC) (pCD8-HTLV-Y479S). Mutations were verified by DNA sequencing using the Sanger dideoxy termination method adapted to the ABI 373A automated sequencer. The pJ.CNstop vector, containing a stop codon downstream of the transmembrane domain of CD8, was used as a positive control for CD8 cell surface expression (38). The pRSV-GFP vector, containing the open reading frame (ORF) of the green fluorescence protein (GFP) under the control of the Rous sarcoma virus long terminal repeat (LTR) promoter, was provided by T. Bordet (Institut Cochin de Génétique Moléculaire, Paris, France).

Flow cytometry. CD8-TM-CD hybrid expression at the cell surface was monitored by flow cytometry. HeLa cells (10⁶) subjected to electroporation with 4 µg of pRSV-GFP and 10 µg of CD8-TM-CD chimera vectors were washed twice with phosphate-buffered saline (PBS) and incubated for 1 h at 4°C with CD8-RD1 antibody diluted in 1% bovine serum albumin (BSA)-PBS (Coulter Coultronics). They were then washed three times with 1% BSA-PBS and fixed in 1% formaldehyde-PBS. Flow cytometry analysis was performed on a Coultronics Epics Elite instrument. Values shown are the averages of three independent experiments. The results for the CD8-TM-CD hybrids were compared to those for the wild type by means of Student's t test for unpaired samples (StatView software package). Values are given as means ± standard error of mean.

Indirect immunofluorescence stainings. HeLa cells (8 × 10⁴) underwent electroporation with 10 µg of CD8-TM-CD chimera vectors, were spread on glass coverslips in 24-well plates, and then were stained for immunofluorescence. The cells on glass coverslips were washed twice with PBS, fixed for 20 min in 4% paraformaldehyde-PBS at room temperature, then quenched by incubation for 10 min in PBS-0.1 M glycine, and permeabilized for 30 min in 0.05% saponin-0.2% BSA-PBS at room temperature. The permeabilized cells were incubated for 45 min at room temperature with CD8-fluorescein isothiocyanate (FITC) antibody (Coulter Coultronics) diluted in 0.05% saponin-0.2% BSA-PBS, washed four times in 0.05% saponin-0.2% BSA-PBS, and mounted with 5 µl of Moviol (Calbiochem) on microscope slides. Confocal microscopy was performed with a Bio-Rad MRC1000 instrument. Optical sections were mounted by using the Adobe Photoshop software package.

Quantitative syncytium formation assay. The HIV-1 LAI env gene was subcloned downstream of the cytomegalovirus (CMV) immediate-early promoter for production of envelope proteins by cells in culture. Briefly, pCMV-HIV1 was constructed by inserting the SalI-SalI fragment from pMA243 (a gift from M. Alizon, Institut Cochin de Génétique Moléculaire in pcDNA3 (Invitrogen) cut by XhoI. pCMV-HIV1-Y712A was obtained by site-directed mutagenesis. HIV-1 LAI Tyr 712 (TAT codon) was replaced by an alanine (GCT). pSRS, containing the SIVmac239 env gene downstream of the simian virus 40 late promoter, was provided by E. Hunter. pSRS-Y721A was obtained by site-directed mutagenesis. The SIVmac239 Tyr 721 (TAT codon) was mutated to an alanine.

Two-hybrid assay. DNA fragments encoding the membrane-proximal Tyr-based motif of the TM-CD of HIV-1 LAI (amino acid residues 707 to 726), SIVmac239 (residues 716 to 733), and HTLV-1 (residues 465 to 488) (Fig. 1) were generated by PCR and cloned in frame with the LexA binding domain (BD) into the pLex10 vector (pLex-HIV1, pLex-SIV, and pLex-HTLV-1, respectively). Point mutations of the essential tyrosine residue of the Tyr-based motifs were constructed by site-directed mutagenesis by PCR using appropriate primers. HIV-1 LAI Env Tyr 712 and SIVmac239 Env Tyr 721 (both with a TAT codon) were mutated to alanine (GCT codon) (pLex-HIV1-Y712A and pLex-SIV-Y721A), HTLV-1 Env Tyr 476 (TAC codon) was changed to Ser (TCC) (pLex-HTLV-Y476S), and HTLV-1 Env Tyr 479 (TAC codon) was replaced by a serine (TCC) (pLex-HTLV-Y479S). Mutations were verified by DNA sequencing using the Sanger dideoxy termination method adapted to the ABI 373A automated sequencer.

View larger version (16K): [in this window] [in a new window]   FIG. 1.   Structures of retroviral TM proteins. The external domain, anchor peptide, and cytoplasmic domain are indicated. Numbering corresponds to the position of the beginning and the end of the cytoplasmic domains. Arrows indicate the position of the truncation corresponding to the membrane-proximal region of HIV-1 LAI and SIVmac239 TM-CD used in two-hybrid and in vitro binding assays (HIV-1 707-726 and SIV 716-733). Canonical YXXØ motifs are underlined and mutated tyrosine residues are in boldface.

In vitro binding assay. DNA fragments containing the membrane-proximal Tyr-based motifs of the TM-CDs of HIV-1 LAI (amino acid residues 707 to 726) and SIVmac239 (residues 716 to 733), or the full-length TM-CDs of HIV-1 LAI Env (amino acid residues 707 to 856), SIVmac239 Env (residues 716 to 879) and HTLV-1 Env (residues 465 to 488), were obtained by PCR and cloned in frame with GST (glutathione S-transferase) into the pGex-2TH vector to generate pGex-HIV, pGex-SIV, pGex-HIV, pGex-SIV, and pGex-HTLV. Point mutations of the essential Tyr residues were introduced into the full-length and truncated TM-CDs by PCR as described above, yielding pGex-HIV-Y712A, pGex-HIV-Y712A, pGex-SIV-Y721A, pGex-SIV-Y721A, pGex-HTLV-Y476S, and pGex-HTLV-Y479S. For in vitro translation and transfection studies, the µ1 and µ2 ORFs were subcloned downstream of the T7 promoter in the pSG-Flag plasmid (a gift from P. Jalinot, Ecole Normale Superieure, Lyon, France). The -, 2-, and -adaptin ORFs were subcloned downstream of the T7 promoter in the pcDNA3 vector (Invitrogen).

HeLa cell lysate binding assay. HeLa cells were lysed in 50 mM Tris-150 mM NaCl-5 mM EDTA-1% Triton X-100 (pH 8). Whole-cell lysates corresponding to 2.5 × 10⁷ cells were incubated overnight at 4°C with 5 µg of wild-type or mutant GST fusion protein or control GST immobilized on GSH-agarose beads. The beads were then washed five times with 5 mM Tris-150 mM NaCl-5 mM EDTA-1% Triton X-100 (pH 8). Bound cellular proteins were separated by SDS-PAGE and revealed by Western blotting with anti- adaptin monoclonal antibody (MAb) (clone 100/3; Sigma) and anti- adaptin MAb (Alexis).

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

Involvement of retroviral membrane-proximal YXXØ-based motifs in the cell surface expression of CD8-TM-CD envelope chimera. Membrane-proximal YXXØ-based motifs, reminiscent of the Tyr-containing internalization signals found in some cell surface proteins (9), are conserved in most retroviral TM-CDs (Fig. 1). To analyze in the same membrane glycoproteins context the involvement of these Tyr-based motifs in cell surface expression of TM proteins, chimeras were constructed by inserting the TM-CD of HIV-1 LAI, SIVmac239, or HTLV-1 downstream of the extracellular and transmembrane domains of the CD8 alpha-chain antigen (pCD8-HIV, pCD8-SIV, or pCD8-HTLV [Fig. 1]). Point mutations of the tyrosine residue of the membrane-proximal Tyr-based motifs were made in constructs pCD8-HIV-Y712A, pCD8-SIV-Y721A, pCD8-HTLV-Y476S, and pCD8-HTLV-Y479S. Cell surface expression of these CD8-TM-CD chimeras was studied by flow cytometry on HeLa cells cotransfected with pRSV-GFP (Fig. 2). Surface expression patterns of the various chimeras are summarized in Table 1. In all experiments, we checked that wild-type and mutated CD8-TM-CD vectors were expressed at similar levels in the GFP⁺ transfected cells, using flow cytometry of permeabilized cells (data not shown) and Western blot analysis with an anti-CD8 antibody (Fig. 2E).

View larger version (45K): [in this window] [in a new window]   View larger version (16K): [in this window] [in a new window]   FIG. 2.   Cell surface expression of CD8-TM-CD chimeras in HeLa cells. (A to D) HeLa cells were cotransfected by electroporation with 10 µg of the pCD8-HIV (A), pCD8-SIV (B), or pCD8-HTLV (C and D) (blue curves) or 10 µg of the pCD8-HIV-Y712A (A), pCD8-SIV-Y721A (B), pCD8-HTLV-Y476S (C), or pCD8-HTLV-Y479S (D) vector (red curves) along with 4 µg of pRSV-GFP vector. Surface expression of CD8 hybrids in GFP+ cells was analyzed by flow cytometry 48 h later. Grey curves, cells transfected with the pRSV-GFP vector alone, as the negative control; black curve, cells transfected with the pJ.CNstop vector, as the positive control (A). Data are representative of three independent experiments. (E) CD8-TM-CD chimera expression in HeLa cells. Cells were transfected with 10 µg of pCD8-HIV (lane 2), pCD8-HIV-Y712A (lane 3), pCD8-SIV (lane 4), pCD8-SIV-Y721A (lane 5), pCD8-HTLV (lane 6), pCD8-HTLV-Y476S (lane 7), pCD8-HTLV-Y479S (lane 8), pCD8-HIV (lane 9), pCD8-HIV-Y712A (lane 10), pCD8-SIV (lane 11), pCD8-SIV-Y721A (lane 12), and pJ.CN stop (lane 13) vectors. Identical quantities of lysates from transfected HeLa cells were analyzed by Western blotting with anti-CD8 antibody H-160 (Santa Cruz Biotechnology). NT, nontransfected control cells. Sizes are indicated in kilodaltons on the right.

Subcellular localization of the CD8-TM-CD chimeric proteins. The subcellular localization of the CD8-TM-CD hybrids in transfected cells was determined by immunofluorescence with anti-CD8-FITC antibodies, using confocal microscopy (Fig. 3). There were intense signals in the periphery of the nuclei of cells transfected with wild-type CD8-HIV, CD8-SIV, and CD8-HTLV chimeras (Fig. 3A, C, and E). There was also some cell surface staining in the CD8-HTLV-transfected cells, while staining in the HIV-1 and SIV CD8 TM-CD chimeras was mostly in a perinuclear area and in peripheric dots in the cytoplasm, and signals were barely detectable at the cell surface (Fig. 3A, C, and E). These results show that most of the wild-type CD8-TM-CD chimeric molecules were retained in an intracellular and perinuclear compartment. However, a higher amount of the CD8-HTLV chimera was detected at the cell surface, indicating that the chimeras were more abundant at the plasma membrane than the CD8-HIV and CD8-SIV chimeras, as demonstrated by flow cytometry (Table 1).

View larger version (37K): [in this window] [in a new window]   FIG. 3.   Localization of CD8-TM-CD hybrids in HeLa cells. HeLa cells were transfected with 10 µg of the pCD8-HIV (A), pCD8-HIV-Y712A (B), pCD8-SIV (C), pCD8-SIV-Y721A (D), pCD8-HTLV (E), pCD8-HTLV-Y476S (F), and pCD8-HTLV-Y479S (G) vectors; 48 h later, the cells were fixed, permeabilized, and stained with an anti-CD8-FITC antibody. The distribution of CD8 hybrids was examined by immunofluorescence staining and confocal microscopy analysis. A representative medial section is shown. Scale bar, 20 µm. Data are representative of three independent experiments.

Tyrosine substitutions increased the fusiogenic capacity of HIV-1, SIV, and HTLV-1 envelope glycoproteins. The effects of mutations in the Tyr-based sorting signals of HIV-1 and SIV TM-CDs on the amounts of the HIV-1, SIV, and HTLV-1 envelope glycoproteins expressed at the cell surface were analyzed in quantitative syncytium formation assays (8, 11). In these assays, the presence of envelope glycoproteins on the surface of transfected cells causes syncytium formation with indicator cells, resulting in Tat-dependent synthesis of -galactosidase.

Interaction of HIV-1, SIV, and HTLV-1 YXXØ-containing sequences with the µ1 and µ2 adaptor subunits. The capacity of the retroviral TM-CDs to physically interact with components of the AP-1 and AP-2 adaptor complexes was assessed in a yeast two-hybrid assay using the L40 reporter strain. The membrane-proximal TM-CD fragments from HIV-1 LAI and SIVmac239, containing their respective Tyr-based sorting signals, and the complete HTLV-1 TM-CD (Fig. 1) were fused to the LexA BD, while the different components of the AP-1 and AP-2 complexes, µ1 or µ2, , 1 or 2, and  chains, were fused to the Gal4 AD. The fragments of HIV-1 and SIV TM-CDs, and the complete HTLV-1 TM-CD, bound efficiently to µ1 and µ2 medium chains, as indicated by the expression of the reporter gene, HIS3, which allows growth in the absence of histidine (Fig. 4, lanes 1 and 4). These retroviral TM-CD fragments did not react with the other subunits of AP-1 (- and 1-adaptins) or AP-2 (- and 2-adaptins) in this two-hybrid assay (Fig. 4 and data not shown). Interactions of the µ1 or µ2 adaptor subunits with the full-length TM-CD of HIV-1 LAI or SIVmac239 were not detectable in these two-hybrid assays unless the C-terminal lentivirus lytic peptides present in lentiviral TM-CDs (16) were removed by deletion (data not shown).

View larger version (23K): [in this window] [in a new window]   FIG. 4.   Interaction of the HIV-1, SIV, and HTLV-1 TM-CD Tyr-based motifs with µ1 and µ2 subunits in the yeast two-hybrid system. The yeast reporter strain L40 was cotransformed with plasmids encoding various Gal4 AD-adaptin hybrids and plasmids encoding the LexA BD fused to TM-CD707-726 of HIV-1 LAI (A), TM-CD716-733 of SIVmac239 (B), or complete TM-CD of HTLV-1 (C). Cotransformants were analyzed for histidine auxotrophy. They were patched on medium with histidine (+His) and then replica plated on medium without histidine (His). Growth in the absence of histidine indicates interaction between hybrid proteins. The positive control was the interaction between Ras and Raf proteins, which bind to each other efficiently (lanes 9). Binding specificity was verified by the absence of interaction between the retroviral tyrosine-based motifs TM-CD and the Gal4 AD alone (A and B, lanes 8).

In vitro interaction of the Tyr-based motifs or full-length TM-CDs of HIV-1, SIV, and HTLV-1 with the µ1 and µ2 adaptor subunits. Results obtained in two-hybrid assay were confirmed by binding studies using in vitro-translated [³⁵S]µl or [³⁵S]µ2 adaptor chain and the membrane-proximal Tyr-based motif of HIV-1 LAI (residues 707 to 726) or SIVmac239 (residues 716 to 733) fused to GST (Fig. 5A and B). Both [³⁵S]µ1 and [³⁵S]µ2 bound to GST-HIV TM-CD (Fig. 5A and B, lane 3) and to GST SIV TM-CD (Fig. 5A and B, lanes 5).

View larger version (46K): [in this window] [in a new window]   FIG. 5.   Interaction of the Tyr-based motifs or full-length TM-CDs of HIV-1, SIV, and HTLV-1 with in vitro-translated µ1 and µ2. µ1 (A, C, and E) and µ2 (B, D, and F) were translated in vitro in rabbit reticulocyte lysate and incubated with identical quantities of GST (lanes 2), GST-HIV (A and B, lanes 3), GST-HIV-Y712A (A and B, lanes 4), GST-SIV (A and B, lanes 5), GST-SIV-Y721A (A and B, lanes 6), GST-HIV (C and D, lanes 3), GST-HIV-Y712A (C and D, lanes 4), GST-SIV (C and D, lanes 5), GST-SIV-Y721A (C and D, lanes 6), GST-HTLV (E and F, lanes 3), GST-HTLV-Y476S (E and F, lanes 4), and GST-HTLV-Y479S (E and F, lanes 5). Bound labeled material was analyzed by SDS-PAGE and autoradiography. One-fifth of the input of µ1 and µ2 in vitro-translated products used for the binding assay was run on lane 1 of each panel.

Recruitment of the AP-1 and AP-2 adaptor complexes to the retroviral TM-CDs. The µ1 and µ2 medium chains, which interact with Tyr-based sorting signals, are believed to serve as recognition components of AP-1 and AP-2 for the recruitment of the whole clathrin-associated adaptor complexes by the cytoplasmic domains of integral membrane proteins (28). We therefore examined whether the full-length retroviral TM-CDs fused to GST, which can interact with the µ subunits (Fig. 5), could also recruit the whole AP-1 or AP-2 complexes from HeLa cell lysates. The AP-1 and AP-2 complexes were revealed by immunoreactivity with anti- adaptin MAb (specific of AP-1) or anti- adaptin MAb (specific of AP-2). Immunoblot analysis of the cell proteins retained on GST-HIV, GST-SIV, and GST-HTLV TM-CDs indicated that both the AP-1 and the AP-2 complexes bound to the three retroviral TM-CDs, (Fig. 6B and 6C, lanes 3 and 5; Fig. 6D and 6E, lanes 3). Binding of the membrane-proximal Tyr-based motif of HIV-1 LAI (residues 707 to 726) or SIVmac239 (residues 716 to 733) to the AP-1 and AP-2 was also tested. GST-HIV and GST-SIV interact efficiently with the AP-1 complexes (Fig. 6A, lanes 3 and 6), whereas no binding of AP-2 complexes was observed on HIV-1 and SIV Tyr-based motifs (data not shown).

Interaction of full-length HIV-1 and SIV TM cytoplasmic domains with in vitro-translated 2-adaptin. Since persistent binding to the AP-1 and AP-2 complexes was observed with Tyr-mutated HIV-1 and SIV TM-CDs (Fig. 6), we examined the binding of in vitro-translated [³⁵S], [³⁵S], and [³⁵S]2 subunits of AP-1 and AP-2 complexes to full-length TM-CDs of HIV-1 or SIV fused to GST. None of the three retroviral GST-TM-CDs tested interacted with the -adaptin subunit of AP-1 or the -adaptin subunit of AP-2 in this assay (data not shown). In contrast, [³⁵S]2 bound to GST-HIV TM-CD (Fig. 7, lane 3) and to GST-SIV TM-CD (Fig. 7, lane 4) but not to GST-HTLV or to GST alone (Fig. 7, lanes 5 and 2, respectively). We also performed this in vitro binding assay with the membrane-proximal Tyr-based motifs of the TM-CDs of HIV-1 LAI (residues 707 to 726) and SIVmac239 (residues 716 to 733) fused to GST (GST-HIV and GST-SIV, respectively). The [³⁵S]2 subunit did not interact with GST-HIV or GST-SIV (Fig. 7, lanes 6 and 7), suggesting that the interaction with [³⁵S]2 occurs in a region distal to the membrane-proximal Tyr-based motif. This interaction may participate in the recruitment of AP complexes, in addition to the binding of the YXXØ-based motif to the µ adaptor subunit.

View larger version (10K): [in this window] [in a new window]   FIG. 6.   Interaction of HIV-1, SIV, and HTLV-1 TM-CDs with the AP-1 and AP-2 complexes. Identical quantities of GST (lanes 2), GST-HIV (A, lane 3), GST-HIV-Y712A (A, lane 4), GST-SIV (A, lane 5), GST-SIV-Y721A (A, lane 6), GST-HIV (B and C, lanes 3), GST-HIV-Y712A (B and C, lanes 4), GST-SIV (B and C, lanes 5), GST-SIV-Y721A (B and C, lanes 6), GST-HTLV (D and E, lanes 3), GST-HTLV-Y476S (D and E, lanes 4), and GST-HTLV-Y479S (D and E, lanes 5), were incubated with HeLa cell lysates (25 × 106 cells). The binding of AP-1 and AP-2 complexes to GST fusion proteins was revealed by Western blotting with anti- adaptin MAb (A, B, and D) and anti- adaptin MAb (C and E). Positions of the -adaptin (Mr, ~100,000) and -adaptin MAb (C and E). Positions of the -adaptin (Mr, ~100,000) and -adaptin (Mr, ~ 104,000) are indicated in the crude cell lysate from 106 cells (lanes 1).

View larger version (35K): [in this window] [in a new window]   FIG. 7.   Interaction of full-length HIV-1, SIV, and HTLV-1 TM-CDs with in vitro-translated 2-adaptin. 2 subunit was translated in vitro in rabbit reticulocyte lysate and incubated with identical quantities of GST (lane 2), GST-HIV TM-CD (lane 3), GST-SIV TM-CD (lane 4), GST-HTLV TM-CD (lane 5), GST-HIV TM-CD (lane 6), and GST-SIV TM-CD (lane 7). Bound labeled material was analyzed by SDS-PAGE and autoradiography. One-fifth of the input of 2 in vitro-translated product used for the binding assay was run on lane 1.

Cell surface and intracellular distribution of CD8-HIV and CD8-SIV truncated chimeras with a mutated membrane-proximal Tyr motif. The involvement of the C-terminal region of HIV-1 and SIV TM-CDs, which binds to 2 subunit, in the cellular distribution of the CD8-TM-CD molecules was determined by deleting this region from the wild-type and the Tyr-mutated CD8-HIV and CD8-SIV chimera. Expression vectors CD8-HIV, CD8-SIV, CD8-HIV-Y712A, and CD8-SIV-Y721A were constructed so as to contain the membrane-proximal fragment of the TM-CD of HIV-1 LAI (amino acid residues 707 to 726) or SIVmac239 (residues 716 to 733). Cells were transfected with a construct and pRSV-GFP. The amount of the CD8-TM-CD chimeras on the cell surface was measured in GFP⁺ transfected cells by flow cytometry. The total amount of CD8-TM-CD chimeras in the transfected cells was monitored by flow cytometry of permeabilized cells and by Western blotting using anti-CD8 antibodies. As shown in Fig. 2E, full-length and truncated CD8-TM-CDs were expressed at levels similar to those in the transfected cells.

View larger version (24K): [in this window] [in a new window]   View larger version (42K): [in this window] [in a new window]   FIG. 8.   Cell surface and intracellular distribution of deleted and mutated CD8-HIV-Y712A and CD8-SIV-Y721A chimeras in HeLa cells. (A and B) HeLa cells were cotransfected by electroporation with 10 µg of the pCD8-HIV-Y712A (blue curve), pCD8-HIV-Y712A (red curve), or pCD8-HIV (black curve) vector (A) or the pCD8-SIV (blue curve), pCD8-SIV-Y721A (red curve), or pCD8-SIV (black curve) (B) vector along with 4 µg of pRSV-GFP vector; 48 h later, the surface expression of CD8 hybrid in GFP+ cells was analyzed by flow cytometry. Grey curves represent cells transfected with the pRSV-GFP vector alone, as the negative control. Data are representative of three independent experiments. (C to F) HeLa cells were transfected with 10 µg of the pCD8-HIV (C), pCD8-HIV-Y712A (D), pCD8-SIV (E), or pCD8-SIV-Y721A (F) vector; 48 h later, cells were fixed, permeabilized, and stained with an anti-CD8-FITC antibody. The distribution of CD8 hybrids was examined by immunofluorescence staining and confocal microscopy analysis. A representative medial section is shown. Scale bar, 20 µm. Data are representative of three independent experiments.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

We have attempted to elucidate the molecular mechanisms governing intracellular trafficking and cell surface expression of the retroviral envelope glycoproteins by investigating the role of the Tyr-based sorting signals in the cytoplasmic domains of HIV-1, SIV, and HTLV-1 transmembrane glycoproteins. We used CD8-TM-CD chimeric molecules, flow cytometry, and immunofluorescence to show that mutation of the conserved membrane-proximal Tyr-based motif results in redistribution of the CD8 chimera. However, the effect of such a mutation on HTLV-1, which has a short TM-CD (24 residues), was different from its effect on HIV-1 and SIV, which have a long TM-CDs (150 and 164 residues, respectively). A mutation of the Tyr 479 residue of the HTLV-1 Tyr-based motif dramatically changed the cellular distribution of the CD8-HTLV chimera. Most of the chimera was at the plasma membrane, with only a small amount still within the cytoplasm (Fig. 2 and 3). By contrast, mutation of the corresponding Tyr residues of the HIV-1 or SIV YXXØ signal to alanine caused a more subtle redistribution of the HIV-1 or SIV CD8 chimera to the cell surface, and a considerable fraction of the chimera was still within the cell. These results suggest that the single or predominant sorting signal in the short HTLV-1 TM-CD is the Tyr-based motif Y₄₇₉SLI. Thus, when the Tyr-based signal is inactivated by the Y479A mutation, internalization and/or intracellular sorting of the CD8-HTLV chimera is inhibited, and most of the chimera molecules stay at the cell surface.

For HIV-1 and SIV, although the HIV-1 Y712A and the SIV Y721A mutations modify the subcellular distribution and the amounts of HIV and SIV CD8 chimeric molecules at the cell surface, a large fraction of these chimeras are still within the cell (Fig. 3). One explanation is that there are sorting signals in addition to the proximal YXXØ-based signal that modulate intracellular trafficking of transmembrane proteins in the HIV-1 and SIV TM-CDs. Thus, the consequences of the mutation of the proximal Tyr-based sorting signal are less pronounced than they are for HTLV-1, since the other potential signals remain unaffected. The differences between HTLV-1 and HIV-1 or SIV may also be because the Tyr-based sorting signal of HIV-1 or SIV are less active than that of HTLV-1. However, studies by flow cytometry and immunofluorescence demonstrated that the HIV-1 or SIV Tyr-based sorting signals are fully functional in the context of a short cytoplasmic tail, since their mutation resulted in altered subcellular distribution, comparable to that observed with the short cytoplasmic domain of HTLV-1. These results suggest that the differences between the full-length HIV/SIV and HTLV-1 TM-CDs indicate that there are additional distal sorting signals in the long lentiviral TM-CDs, while the Tyr-based signal is probably the dominant sorting signal in the short HTLV-1 TM-CD.

What are the molecular interactions responsible for the activity of these sorting signals? We attempted to describe the interactions between adaptor complexes of clathrin-coated vesicles and the HIV-1, SIV, and HTLV-1 TM-CD Tyr-based signals. We used two-hybrid assays to demonstrate that both the µ1 and µ2 subunits of AP-1 and AP-2 complexes were capable of interacting directly with the Tyr-based motif of HIV-1 and SIV and with the short TM-CD of HTLV-1. Site-directed mutagenesis studies showed that these interactions depend on the tyrosine residue of the conserved membrane-proximal YXXØ motifs. The full-length TM-CDs of HIV-1, SIV, and HTLV-1 not only bind efficiently to the isolated µ chains but also recruit the whole AP-1 and AP-2 adaptor complexes. Replacement of the Tyr 479 residue of the YXXØ motif (YSLI) in HTLV-1 by a Ser residue completely abrogated binding to the AP-1 and AP-2 adaptor complexes, and mutation of the Tyr 476 residue diminished the binding to AP-1 complexes and inhibited the interaction with the AP-2 complexes. These results show that the HTLV-1 Tyr-based motif involving Tyr 479 is critical for the binding to the whole adaptor complexes and that residues surrounding this Tyr-based motif, such as Tyr 476, also contribute to this interaction with the AP complexes. Thus, the Y₄₇₉SLI Tyr-based sorting signal mediates the cell surface expression of HTLV-1 envelope glycoprotein via its direct interaction with the adaptor complexes.

The membrane-proximal Tyr-based motif is not the only sequence in the unusually long HIV-1 and SIV TM-CDs involved in the recruitment of the clathrin-associated adaptor complexes. Mutation of the membrane-proximal Tyr-based motifs reduced binding of HIV-1 and SIV full-length TM-CDs to AP-1 complexes only slightly and had no apparent effect on AP-2 recruitment. By contrast, these mutations inhibited the interaction between AP-1 and truncated HIV-1 or SIV TM-CDs, and no binding could be detected between these truncated TM-CDs and AP-2 complexes. We therefore postulate that other determinants are implicated in the recruitment of the AP-1 and AP-2 complexes by the HIV-1 and SIV TM-CDs. A conserved and more distal Tyr-based motif, YHRL in HIV-1 (position 768 to HIV-1 TM) or YQIL in SIV cytoplasmic domain (position 795 to SIV TM), could be part of these additional determinants. However, data showing that this distal tyrosine motif in the HIV-1 TM-CD is not required for envelope endocytosis (36) suggest the involvement of other determinants of HIV-1 and SIV TM-CDs in the binding to the µ subunits to recruit the adaptor complexes.

Other subunits (such as -, -, -, or -adaptin) of the adaptor complexes could also be involved in the recruitment of the envelope glycoproteins to the clathrin-coated pits. Such interactions have been described previously for the epidermal growth factor receptor (27), for the Eps15 protein which binds to this receptor (5), and for the asialoglycoprotein receptor (3). Multiple sorting signals have also been identified in the cytoplasmic domains of several molecules, including the low-density lipoprotein receptor (26) and the insulin receptor (32), which have two tyrosine-containing determinants, and the T-cell receptor CD3  and  chains, which contain a dileucine motif and a Tyr-based motif (21). We found no evidence for interaction between any of the three retroviral membrane-proximal fragments which contain the Tyr-based motifs and the -, -, or -adaptin subunit of AP-1 or AP-2 adaptor complexes, but we could demonstrate that the HIV-1 and SIV full-length TM-CDs interact with 2-adaptin via determinants in the distal C-terminal region of the TM-CDs (Fig. 7). Thus, these distal determinants may also participate in the recruitment of the AP-1 and AP-2 complexes. Recent studies (33) have shown that the 1 subunit of the AP-1 complex interacts directly with dileucine-based motifs, which are implicated in sorting and trafficking of a wide variety of membrane proteins (1, 17, 21, 25, 42). Since the 1- and 2-adaptins are closely related (85% identity and 92% similarity) and both may be present in either AP-1 or AP-2 complexes (25), we postulate that some of the dileucine or the leucine-isoleucine pairs of residues in the C-terminal region of the SIV and HIV TM-CDs could be involved in such interactions.

Tyrosine-sorting signals are conserved in the TM-CDs of most retroviral envelope proteins and also in the cytoplasmic domains of membrane glycoproteins of other enveloped viruses, such as vesicular stomatitis virus and varicella-zoster virus (2, 41). Sorting and trafficking of the envelope proteins by clathrin-associated adaptor complexes could allow the transient appearance of the envelope proteins at the surface of infected cells to ensure optimal incorporation of the envelope into infectious virions through envelope-matrix interactions at the plasma membrane. This Tyr-based signal could also limit the susceptibility of infected cells to humoral and cellular responses by reducing the amount of envelope glycoprotein on the surface of infected cells and thus help the virus establish a persistent infection in vivo.