An orderly inactivation of intracellular retention signals controls surface expression of the T cell antigen receptor

doi:10.1084/jem.20041133

Published 22 February 2005. doi:10.1084/jem.20041133
Rockefeller University Press, 0022-1007 $8.00
JEM, Volume 201, Number 4, 555-566

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ARTICLE

An orderly inactivation of intracellular retention signals controls surface expression of the T cell antigen receptor

Pilar Delgado and Balbino Alarcón

Centro de Biología Molecular Severo Ochoa, Consejo Superior de Investigaciones Científicas, Universidad Autónoma de Madrid, Madrid 28049, Spain

CORRESPONDENCE Balbino Alarcón: Balarcon{at}cbm.uam.es

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Abstract
Results
Discussion
MATERIALS AND METHODS
References

Exit from the endoplasmic reticulum (ER) is an important checkpointfor proper assembly of multimeric plasma membrane receptors.The six subunits of the T cell receptor (TCR; TCR ${alpha}$ , TCRß,CD3 ${gamma}$ , CD3 ${delta}$ , CD3 ${varepsilon}$ , and CD3 ${zeta}$ ) are each endowed with ER retention/retrievalsignals, and regulation of its targeting to the plasma membraneis therefore especially intriguing. We have studied the importanceof the distinct ER retention signals at different stages ofTCR intracellular assembly. To this end, we have characterizedfirst the presence of ER retention signals in CD3 ${gamma}$ . Despite thepresence of multiple ER retention signals in CD3 ${gamma}$ , ${varepsilon}$ ${gamma}$ dimers reachthe cell surface when the single CD3 ${varepsilon}$ ER retention signal isdeleted. Furthermore, inclusion of this CD3 ${varepsilon}$ mutant promotedplasma membrane expression of incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ and ${alpha}$ ß ${delta}$ ${varepsilon}$ complexes without CD3 ${zeta}$ . It therefore appears that the CD3 ${varepsilon}$ ERretention signal is dominant and that it is only overriddenupon the incorporation of CD3 ${zeta}$ . We propose that the stepwiseassembly of the TCR complex guarantees that all assembly intermediateshave at least one functional ER retention signal and that onlya full signaling-competent TCR complex is expressed on the cellsurface.

Abbreviation used: MFI, mean fluorescence intensity.

Multimeric plasma membrane protein complexes typically assembleearly in the secretory pathway, in parallel with the synthesisand folding of individual subunits in the ER. Exit from theER is an important checkpoint for many such complexes, as onlyfully assembled complexes are allowed to pass this control step(1). ER retention/retrieval signals (herein referred to as ERretention signals) are present in some receptor subunits, andthe assembly of complexes is thought to mask the ER retentionsignal, permitting targeting to the membrane of the fully assembledcomplexes (2). The TCR is an especially complex model becauseit is formed by six different subunits that all contain ER retentiondeterminants.

In the TCR, the TCR ${alpha}$ and TCRß subunits (or TCR ${gamma}$ andTCR ${delta}$ in ${gamma}$ ${delta}$ T cells) are responsible for the recognition of theMHC/antigen ligand. These are noncovalently bound to the signal-transducingsubunits CD3 ${gamma}$ , CD3 ${varepsilon}$ , CD3 ${delta}$ , and CD3 ${zeta}$ (the CD3 ${zeta}$ subunit is CD247).During assembly, CD3 ${varepsilon}$ first dimerizes with either CD3 ${gamma}$ or CD3 ${delta}$ ,and the resulting ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers associate with the TCR ${alpha}$ and TCRßsubunits (3–5). The resulting ${alpha}$ ß ${gamma}$ ${varepsilon}$ or ${alpha}$ ß ${delta}$ ${varepsilon}$ complexes are either retained in the ER or degraded in lysosomes(6). Only when CD3 ${zeta}$ is incorporated into the complex is the TCRtransported to the plasma membrane (6–8). In this way,expression of signal-transducing subunits independent of ligand-bindingsubunits or vice versa is tightly controlled. Indeed, in T cellmutants and knockout mice lacking TCRß, CD3 ${varepsilon}$ , or CD3 ${zeta}$ ,TCR expression is severely impaired (9–12). In addition,T cell precursors in RAG-deficient and SCID mice that are unableto express the TCR gene subunits have a very low level of CD3 ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimer expression at the cell surface (13, 14), and theirdevelopment is arrested at the most immature CD4^– CD8^–stage.

Removal of the ER retention signal in the cytoplasmic tail ofCD3 ${varepsilon}$ permits this subunit to reach the cell surface by itself(15, 16). This signal consists of an elongated ${alpha}$ helix followedby a ßI' turn and contains three important, closelyspaced residues: tyrosine, leucine, and arginine. The presenceof arginine in the ER retention signal is characteristic oftype II proteins despite the fact that CD3 ${varepsilon}$ is a type I membraneprotein (17–19). Other ER retention signals in the TCRhave not been analyzed in detail, although TCR ${alpha}$ contains an ERretention signal in its transmembrane region (20) and TCRßin both its extracellular and transmembrane domains (21). Withregard to the other CD3 subunits, CD3 ${gamma}$ has a conserved arginineresidue in position –3 from the COOH terminus, and CD3 ${delta}$ has either an arginine or a lysine residue at the same position.Their removal from Tac ${gamma}$ and Tac ${delta}$ chimeras disrupts ER retention(22).

In addition to ER retention signals, binding of incompletelyfolded subunits and complexes to chaperonins such as calnexincan also influence ER retention (23). Moreover, endocytosissignals in several subunits of the TCR complex offer a furtherlevel of regulation (22, 24, 25). The CD3 ${gamma}$ subunit contains animportant double leucine signal for endocytosis that is hiddenin the complete TCR complex but unmasked by PKC-mediated phosphorylationof an upstream serine (26). In partial complexes, this doubleleucine signal is constitutively exposed and only masked uponintegration of CD3 ${zeta}$ into the TCR complex (27, 28).

During assembly, all individual ER retention determinants inTCR subunits must be annulled before the TCR complex can betransported to the plasma membrane. The ER retention determinantsmay become progressively overridden as the TCR complex assemblesor alternatively, all determinants might become inoperativeat once, when all the TCR subunits are assembled. To study thisprocess, we have characterized the ER retention signals in CD3 ${gamma}$ and analyzed the predominance of CD3 ${gamma}$ and CD3 ${varepsilon}$ signals in the ${varepsilon}$ ${gamma}$ dimer. All the determinants in CD3 ${gamma}$ are overridden when it assembleswith CD3 ${varepsilon}$ . However, the single ER retention signal in CD3 ${varepsilon}$ remainsactive in the ${varepsilon}$ ${gamma}$ dimer and only becomes inoperative upon completionof the last assembly step, i.e., the incorporation of CD3 ${zeta}$ . Theseresults support a model of sequential inactivation of ER retentionsignals during stepwise assembly.

Results

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Abstract
Results
Discussion
MATERIALS AND METHODS
References

The cytoplasmic tail of CD3 ${gamma}$ contains multiple intracellular trafficking signals
To identify ER retention signals in the cytoplasmic tail ofCD3 ${gamma}$ , a chimeric protein containing the CD3 ${gamma}$ cytoplasmic tailappended to the human CD4 extracellular and transmembrane domainswas generated (chimera 44 ${gamma}$ ; Fig. 1 A). The chimera was transfectedinto COS cells, and cell surface expression was analyzed byflow cytometry. Expression of the 44 ${gamma}$ chimera at the cell surfacewas 2.5-fold lower than that of wild-type CD4 (Fig. 1 B). Furthermore,unlike CD4, the 44 ${gamma}$ chimera was predominantly located in theER of transfected COS cells, with a similar distribution toCD3 ${gamma}$ (Fig. S1, available at http://www.jem.org/cgi/content/full/jem.20041133/DC1).These results indicated that the cytoplasmic tail of CD3 ${gamma}$ containsan ER retention signal.

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Figure 1. Deletion mapping of ER retention sequences in the cytoplasmic tail of CD3 ${gamma}$ . (A) Schematic representation of the 44 ${gamma}$ chimera with the extracellular and transmembrane domains of CD4 and the cytoplasmic tail of CD3 ${gamma}$ . The full amino acid sequence of the CD3 ${gamma}$ tail is shown. The numbers refer to the position of cytoplasmic amino acids in CD3 ${gamma}$ . The di-leucine endocytosis motif is underlined, the two tyrosines of the ITAM are circled, and the putative DxE ER export motif is in bold. The last amino acid in each of the five COOH-terminal deletions is indicated. (B) Surface expression of the 44 ${gamma}$ deletion mutants. COS cells were transfected with the indicated constructs and analyzed by flow cytometry after staining with anti-CD4 antibody. Normalized surface expression was calculated after multiplying the percentage (nonpermeabilized/permeabilized samples) by the MFI of CD4⁺ cells. (C) Surface expression of the 44 ${gamma}$ deletion mutants in the YT human NK cell line. 20–30 stable clones for each of the constructs was analyzed after staining with anti-CD4 and flow cytometry. Surface expression in the four clones with the highest anti-CD4 staining per construct is represented as MFI. (D) Acquisition of partial endo-H resistance of 44 ${gamma}$ deletion mutants. COS cells were transfected with the indicated constructs, pulse-labeled with ³⁵S-methionine, and chased for the indicated times. Immunoprecipitation was performed with an anti-CD4 antibody. Each immunoprecipitate was split, and one half was digested with Endo-H. (E) The rate of ER export for 44 ${gamma}$ chimeras was calculated from the rate of conversion to partial endo-H resistance. The two bands appearing upon digestion with endo-H (D) represent a fully endo-H–sensitive (lower band) and a partly endo-H–resistant (upper band) form of 44 ${gamma}$ . Both protein bands were quantified by densitometry and the ratio of the upper band to the sum of both bands was taken as the endo-H resistance conversion rate and as the rate of ER export.

To characterize this putative ER retention signal, five deletionmutants of the 44 ${gamma}$ chimera were generated and transfected intoCOS cells (Fig. 1 A). Deletion of the three COOH-terminal aminoacids (44 ${gamma}$ ${Delta}$ 1) promoted a moderate increase in surface expressionof the chimera (Fig. 1 B). This effect was slightly accentuatedwhen five or nine additional amino acids were deleted from theCOOH-terminal end (44 ${gamma}$ ${Delta}$ 2 and 44 ${gamma}$ ${Delta}$ 3). In contrast, deletion of sevenmore amino acids (44 ${gamma}$ ${Delta}$ 4) provoked an important reduction in 44 ${gamma}$ expression (Fig. 1 B), suggesting that a signal that facilitatestransport to the plasma membrane might reside between aminoacids 142 and 148. Finally, deletion of most of the cytoplasmictail, including the double leucine endocytotic signal, enhancedsurface expression to above the levels of wild-type CD4. Thiscould be due to the 44 ${gamma}$ ${Delta}$ 5 mutant lacking not only the double leucineendocytotic signal of CD3 ${gamma}$ , but also that of the cytoplasmictail of CD4 (29). The increase in surface expression of themutant chimeras was coincident with a redistribution of thechimera to the Golgi apparatus, plasma membrane, and vesicularstructures (Fig. S1).

The fact that some 44 ${gamma}$ chimera was detected at the plasma membranemight be due to excessive protein expression in transfectedCOS cells, thereby overriding the ER retention machinery. Hence,we studied the surface expression of the 44 ${gamma}$ chimera in stabletransfectants of the human NK cell line YT. Several cell cloneswith each construct were studied to exclude clonal effects.Only the mutant 44 ${gamma}$ ${Delta}$ 5 was expressed at the cell surface at a levelthat matched that of wild-type CD4 (Fig. 1 C). There was onlya slight increase in surface expression of chimeras 44 ${gamma}$ ${Delta}$ 1 through44 ${gamma}$ ${Delta}$ 3 and a marginal reduction of 44 ${gamma}$ ${Delta}$ 4.

We determined how the rate of exit from the ER was affectedin these 44 ${gamma}$ mutants. Human CD4 has two N-glycosylation sites,one of which is converted to the complex type in the matureprotein (30). Hence, we assessed the acquisition of partialendo-H resistance of the 44 ${gamma}$ mutants after metabolic labelingof the COS cells. Export from the ER of the 44 ${gamma}$ ${Delta}$ 1 and 44 ${gamma}$ ${Delta}$ 2 chimeraswas accelerated twofold. These mutants required 50 min to acquire50% endo-H resistance (t_1/2 = 50) compared with the 95 min forwild-type 44 ${gamma}$ (Fig. 1, D and E). Deletion of further amino acidsreduced the exit rate to t_1/2 = 115 min for 44 ${gamma}$ ${Delta}$ 3, whereas theER export of 44 ${gamma}$ ${Delta}$ 4 and 44 ${gamma}$ ${Delta}$ 5 was dramatically reduced (t_1/2 >> 120min). Thus, it seemed clear that signals other than those forER retention also regulate the level of 44 ${gamma}$ chimera surface expression.

The cytoplasmic tail of CD3 ${gamma}$ contains a di-leucine endocytoticmotif (Fig. 1 A; reference 25) and a putative DxE ER exportsignal (31). The combination of ER retention, export, and endocytosisis ultimately responsible for the surface expression of the44 ${gamma}$ mutants. Deletion of the ER retention signal in the COOH-terminalend of the chimera might explain the accelerated rate of ERexport for 44 ${gamma}$ ${Delta}$ 1 and 44 ${gamma}$ ${Delta}$ 2, whereas removal of the putative DxEER export signal would explain the decrease in ER export of44 ${gamma}$ ${Delta}$ 4 and 44 ${gamma}$ ${Delta}$ 5. The diminished ER exit of 44 ${gamma}$ ${Delta}$ 3 compared with 44 ${gamma}$ ${Delta}$ 2might be due to a positional effect on the DxE signal. Nevertheless,it seems that the di-leucine endocytotic signal is mainly responsiblefor regulating the surface levels of the 44 ${gamma}$ chimera. This couldexplain why only 44 ${gamma}$ ${Delta}$ 5 is highly expressed at the surface despitethe reduced rate of ER export (Fig. 1, B, C, and E).

CD3 ${gamma}$ contains ER retention determinants in its extracellular, transmembrane, and cytoplasmic domains
To further characterize this ER retention signal and to determinethe impact this signal has on 44 ${gamma}$ chimera surface expression,point mutations of the last three amino acids were introduced.To avoid interference from the di-leucine internalization signal,leucine 131 was replaced by alanine. Expression of the doublemutants at the cell surface was analyzed in transfected COScells and in stable YT transfectants. In both cell types, mutationof the di-leucine motif alone (44 ${gamma}$ _L131A mutant) caused a two-(COS cells) to sixfold (YT cells) increase in surface expressionof the 44 ${gamma}$ chimera (Fig. 2 A). Replacement of arginine 158 withalanine (44 ${gamma}$ _L131A/R158A mutant) resulted in an additional two-(COS cells) to fourfold (YT cells) increase in surface expression.In contrast, mutation of the other two COOH-terminal amino acids(44 ${gamma}$ _L131A/N160A and 44 ${gamma}$ _L131A/R159A mutants) did not have a majorimpact on cell surface expression. The effect of arginine 158mutation was also reflected in the cellular redistribution ofthis 44 ${gamma}$ mutant (Fig. S2, available at http://www.jem.org/cgi/content/full/jem.20041133/DC1).Thus, of the three amino acid residues deleted in mutant 44 ${gamma}$ ${Delta}$ 1,only arginine 158 seems to be important for ER retention of44 ${gamma}$ .

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Figure 2. CD3 ${gamma}$ contains ER retention determinants in its extracellular, transmembrane, and cytoplasmic domains. (A) Arginine to alanine substitution at position 158 increases the surface expression of the 44 ${gamma}$ chimera. Single or double point mutants of 44 ${gamma}$ were either transiently transfected in COS cells or stably transfected in YT cells, and cell surface expression of the chimera was analyzed by flow cytometry. (B) Intracellular distribution of mutants in the cytoplasmic tail of CD3 ${gamma}$ . COS cells were transfected with constructs featuring single point mutations in either the double leucine endocytosis motif or the cytoplasmic ER retention signal, or with a double mutant ( ${gamma}$ _L131A/R158A), and their expression pattern was analyzed by confocal microscopy after staining with anti-HA mAb. A mutant of CD3 ${gamma}$ lacking the cytoplasmic domain ( ${gamma}$ tr) was analyzed in the same way. (C) Domain-shuffling CD4-CD3 ${gamma}$ chimeras. The CD3 ${gamma}$ domains are dotted. (D) Intracellular distribution of domain- shuffling chimeras in COS cells. COS cells were transfected with the indicated chimeras and analyzed by confocal microscopy after staining with anti-CD4 (for CD4 and 44 ${gamma}$ ) or anti-HA (for HA-tagged ${gamma}$ 44 and 4 ${gamma}$ 4). (E) Surface expression of domain-shuffled chimeras and CD3 ${gamma}$ point mutants. COS cells transfected as in B and D were analyzed by flow cytometry for surface expression after staining with anti-HA or anti-CD4 antibodies.

Once an ER retention signal had been identified in the cytoplasmictail of CD3 ${gamma}$ , we evaluated the role of this signal in the contextof the whole CD3 ${gamma}$ molecule. Surprisingly, mutation of arginine158 to alanine in CD3 ${gamma}$ did not prevent ER retention, becausethe mutant was exclusively located in the ER when examined byconfocal microscopy (Fig. 2 B). Nor was CD3 ${gamma}$ redistributed tothe plasma membrane when an additional mutation in the di-leucinemotif was introduced (Fig. 2 B, ${gamma}$ _L131A/R158A). These resultssuggested that CD3 ${gamma}$ contains other ER retention determinantsin addition to the COOH-terminal signal. Furthermore, a truncatedCD3 ${gamma}$ with only the first two cytoplasmic amino acids of CD3 ${gamma}$ wasstill retained in the ER in COS cells, suggesting that ER retentiondeterminants were present in the extracellular and/or transmembranedomains (Fig. 2 B, ${gamma}$ tr). Indeed, two new domain shuffle chimeraswere both retained in the ER: ${gamma}$ 44, with the extracellular domainof CD3 ${gamma}$ , and 4 ${gamma}$ 4, with the CD3 ${gamma}$ transmembrane domain (Fig. 2, C and D).

Expression of the CD4/CD3 ${gamma}$ chimeras and of the CD3 ${gamma}$ point mutantswas also evaluated by flow cytometry. Surface expression ofthe single di-leucine motif mutant of CD3 ${gamma}$ ( ${gamma}$ _L131A) was slightlyhigher than the wild-type CD3 ${gamma}$ but lower than the mutant in thecytoplasmic ER retention signal (Fig. 2 E, ${gamma}$ _R158A). The doublemutation of the cytoplasmic ER and endocytotic signals ( ${gamma}$ _L131A/R158A)acted synergistically to increase the surface expression ofCD3 ${gamma}$ . Nevertheless, all CD4-CD3 ${gamma}$ chimeras and CD3 ${gamma}$ mutants wereexpressed at lower levels than CD4 (Fig. 2 E), further indicatingthat ER retention determinants reside not only in the cytoplasmictail of CD3 ${gamma}$ , but also in the transmembrane and extracellulardomains. These extracellular and transmembrane retention determinantsin CD3 ${gamma}$ could represent distinct sequence motifs or an unfoldedstate of the protein. In any case, it appears that in contrastto CD3 ${varepsilon}$ , which contains a single ER retention signal (15), retentionof free CD3 ${gamma}$ is regulated by multiple signals. It therefore seemsthat the expression of CD3 ${gamma}$ on the cell surface is tightly regulated.

Dimerization with CD3 ${varepsilon}$ abolishes all ER retention determinants in CD3 ${gamma}$
One of the earliest steps in TCR assembly is the dimerizationof CD3 ${varepsilon}$ with either CD3 ${gamma}$ or CD3 ${delta}$ (3, 4, 6). The resulting ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers are retained in the ER unless they assemble with TCR ${alpha}$ ,TCRß, and CD3 ${zeta}$ . Because both CD3 ${gamma}$ and CD3 ${varepsilon}$ contain ERretention signals, we examined the relative contribution ofeach signal to dimer retention. COS cells were cotransfectedwith the CD3 ${gamma}$ mutants and CD4 chimeras (refer to Fig. 2) andeither wild-type CD3 ${varepsilon}$ or a deletion mutant of CD3 ${varepsilon}$ lacking itssingle ER retention signal ( ${varepsilon}$ mut; reference 15). The 4 ${gamma}$ 4 chimerawas excluded from this study because it lacks the extracellulardomain of CD3 ${gamma}$ necessary for assembly with CD3 ${varepsilon}$ (32). Cellulardistribution of the dimers was distinguished from that of thesingle chains by immunostaining with a CD3 dimer-specific antibody,UCHT1 (33). When associated with wild-type CD3 ${varepsilon}$ , all CD3 ${gamma}$ chimerasand mutants were located in the ER, independent of the presenceof CD3 ${gamma}$ ER retention and endocytotic signals (Fig. 3 A). However,transfection of ${varepsilon}$ mut resulted in export of the ${varepsilon}$ ${gamma}$ dimers from theER and targeting to the plasma membrane (Fig. 3, A and B). Thesame effect was seen when wild-type CD3 ${delta}$ and ${varepsilon}$ mut were expressedin COS cells (not depicted).

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Figure 3. Deletion of the single ER retention signal in CD3 ${varepsilon}$ is sufficient for surface expression of the ${varepsilon}$ ${gamma}$ dimer. (A) Intracellular distribution of the ${varepsilon}$ ${gamma}$ dimer comprising combinations of wild-type and mutant CD3 ${gamma}$ and CD3 ${varepsilon}$ . COS cells were transfected with combinations of either wild-type CD3 ${varepsilon}$ or the ER retention mutant ${varepsilon}$ mut and the indicated CD3 ${gamma}$ mutants. Cells were double stained with anti-HA antibody (green) to identify both free and CD3 ${varepsilon}$ -associated CD3 ${gamma}$ and with UCHT1 (red) to identify the ${varepsilon}$ ${gamma}$ dimer. Cells transfected with wild-type CD3 ${varepsilon}$ or ${varepsilon}$ mut were stained with anti-CD3 ${varepsilon}$ antibody SP34. (B) Surface expression of the ${varepsilon}$ ${gamma}$ dimer. The transfected cells described in A were also analyzed for surface expression of the ${varepsilon}$ ${gamma}$ dimer by flow cytometry after staining with UCHT1.

In the absence of the CD3 ${varepsilon}$ ER retention signal, the ${varepsilon}$ ${gamma}$ dimer wastransported to the cell surface regardless of the CD3 ${gamma}$ cytoplasmicER retention signal (compare ${gamma}$ _R158A with ${gamma}$ in Fig. 3 B). However,mutation of the CD3 ${gamma}$ di-leucine endocytosis signal increasedcell surface expression of the ${varepsilon}$ ${gamma}$ dimer fourfold (Fig. 3 B, ${gamma}$ _L131A).Expression did not increase further when the cytoplasmic ERretention signal of CD3 ${gamma}$ was mutated as well as the endocytoticsignal ( ${gamma}$ _L131A/R158A), nor in the absence of the whole cytoplasmictail ( ${gamma}$ tr), nor in the absence of both the transmembrane andcytoplasmic domains ( ${gamma}$ 44).

These results suggest that the only functional ER retentionsignal in the ${varepsilon}$ ${gamma}$ dimer is that in CD3 ${varepsilon}$ , and all ER retention determinantsin CD3 ${gamma}$ are abrogated upon dimerization with CD3 ${varepsilon}$ . Therefore,the ER retention determinants in CD3 ${gamma}$ do not seem to play a majorrole in regulating ${varepsilon}$ ${gamma}$ expression at the cell surface. However,CD3 ${gamma}$ does contribute to this task by mediating the endocytosisof the ${varepsilon}$ ${gamma}$ dimer via its di-leucine signal.

The single ER retention signal of CD3 ${varepsilon}$ is only overridden during the last assembly step
Once ${varepsilon}$ ${gamma}$ (or ${varepsilon}$ ${delta}$ ) dimers are assembled in the ER, they associate withthe TCR ${alpha}$ and TCRß chains to form ${alpha}$ ß ${gamma}$ ${varepsilon}$ and ${alpha}$ ß ${delta}$ ${varepsilon}$ complexes. These incomplete TCR–CD3 complexes remain inthe ER or are degraded in lysosomes. The TCR complex can onlyreach the plasma membrane when the ${zeta}$ subunit is incorporated(6–8, 34). Indeed, reconstruction of the TCR complex inHeLa cells showed that transfection of the ${zeta}$ subunit was sufficientto drive transport of ${alpha}$ ß ${gamma}$ ${varepsilon}$ ${zeta}$ and ${alpha}$ ß ${delta}$ ${varepsilon}$ ${zeta}$ complexesto the cell surface (35). Bearing this in mind, we studied whetherthe CD3 ${varepsilon}$ ER retention mutant promoted surface expression of the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex or whether assembly of ${zeta}$ was still required.COS cells were transfected with plasmids encoding these subunits,but the ${gamma}$ _L131A mutant was used to avoid internalization of the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex. When transfected with the CD3 ${varepsilon}$ ER retentionmutant, both the CD3 ${gamma}$ ${varepsilon}$ dimer and TCRß were transportedto the plasma membrane, even in the absence of ${zeta}$ (Fig. 4 A).Two-color flow cytometry with anti-TCRß and anti-CD3 ${gamma}$ ${varepsilon}$ antibodies was used to quantify the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex on thecell surface. This showed that the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex is expressedat a high level independent of ${zeta}$ (Fig. 4 B). In contrast, whenwild-type CD3 ${varepsilon}$ was transfected, TCRß and the CD3 ${gamma}$ ${varepsilon}$ dimerwere predominantly found in the ER and were consequently practicallyundetectable at the cell surface (Fig. 4, A and B). Similarresults were obtained when wild-type CD3 ${gamma}$ instead of the di-leucinemutant was used, although surface expression of the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex reached lower levels (Fig. S3, available at http://www.jem.org/cgi/content/full/jem.20041133/DC1),probably because the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex was being endocytosed.These results show that mutation of the CD3 ${varepsilon}$ ER retention signalis sufficient for transport and expression of the incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex to the cell surface. Interestingly, thepresence of ${zeta}$ did not induce a major increase in the surfaceexpression of complexes containing wild-type CD3 ${varepsilon}$ , possibly dueto the inefficient assembly of CD3 ${zeta}$ into the ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex.

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Figure 4. Deletion of the single ER retention signal in CD3 ${varepsilon}$ is sufficient for surface expression of the incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex. (A) Intracellular distribution of the TCR–CD3 chains in cells transfected with wild-type CD3 ${varepsilon}$ or the ${varepsilon}$ mut ER retention mutant. COS cells were transfected with the constructs indicated on the right, permeabilized, and triple stained with the anti- ${varepsilon}$ ${gamma}$ antibody UCHT1 (green), anti-TCRß antibody Jovi.1 (red), and anti-CD3 ${zeta}$ antibody 448 (blue) before analyzing by confocal microscopy. A higher magnification of the area shown in the insets illustrates the presence of the TCR complexes in the ER or the plasma membrane. (B) Surface expression of the incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex. Transfected cells described in A were double stained with mAbs specific for TCRß and the ${varepsilon}$ ${gamma}$ dimer in nonpermeabilized and detergent- permeabilized cells. The percentage of double labeled cells is indicated in each histogram. The percentage of surface expression was calculated from the surface to intracellular expression ratio.

To confirm that the CD3 ${varepsilon}$ ER retention signal is also dominantin the complexes lacking CD3 ${zeta}$ ( ${alpha}$ ß ${gamma}$ ${varepsilon}$ and ${alpha}$ ß ${delta}$ ${varepsilon}$ ) inT cells, we transfected human wild-type CD3 ${varepsilon}$ and human ${varepsilon}$ mut intothe CD3 ${zeta}$ -deficient mutant MA5.8 of the murine hybridoma 2B4 (36).Human CD3 ${varepsilon}$ can assemble with murine TCR chains, and its cellsurface expression can be followed by flow cytometry with anti–humanCD3 antibodies (37). Stable transfectants were analyzed by two-colorflow cytometry using an anti–human CD3 dimer antibodyand an anti-murine TCRß antibody. Transfection ofhuman wild-type CD3 ${varepsilon}$ in ${zeta}$ -sufficient 2B4 cells led to its incorporationinto a sizeable population that was not observed in ${zeta}$ -deficientMA5.8 cells (Fig. 5 A). However, transfection of ${varepsilon}$ mut led toits expression in both the ${zeta}$ -expressing and ${zeta}$ -deficient cell lines,although it was expressed less in the absence of CD3 ${zeta}$ . The levelof human CD3 ${varepsilon}$ expression on the cell surface was also examinedwith an anti-CD3 ${varepsilon}$ antibody in flow cytometry and compared withits intracellular expression in detergent-permeabilized cells.Wild-type CD3 ${varepsilon}$ clearly failed to reach the cell surface in ${zeta}$ -deficientcells despite the intracellular accumulation of the protein(Fig. 5 A). Finally, all the transfectants were surface biotinylatedand the human CD3 ${varepsilon}$ -containing complexes were recovered with ananti–human CD3 antibody. The immunoprecipitates were resolvedby two-dimensional SDS-PAGE under nonreducing/reducing conditionsand showed that ${varepsilon}$ mut was indeed expressed at the cell surfaceand was associated with the murine TCR ${alpha}$ , TCRß, CD3 ${gamma}$ ,CD3 ${delta}$ , and CD3 ${varepsilon}$ chains (Fig. 5 B). Wild-type human CD3 ${varepsilon}$ was againnot detected in ${zeta}$ -deficient cells.

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Figure 5. Deletion of the ER retention signal in CD3 ${varepsilon}$ is sufficient to allow surface expression of the TCR complex in ${zeta}$ -deficient T cells. (A) Surface expression of TCR complexes in ${zeta}$ -expressing and ${zeta}$ -deficient T cells. The parental murine T cell hybridoma 2B4 and its ${zeta}$ -deficient MA5.8 mutant were stably transfected with either wild-type human CD3 ${varepsilon}$ or with human ${varepsilon}$ mut. Cells were double stained with the anti-murine TCRß antibody H57-597 and the anti–human CD3 antibody Leu4 and analyzed by two-color flow cytometry (top). Representative clones for each condition are shown. The result of single staining with anti–human CD3 ${varepsilon}$ antibody SK7 of intact or detergent-permeabilized cells is shown in the middle and bottom rows. (B) The ER retention mutant of CD3 ${varepsilon}$ is expressed at the cell surface within a TCR complex. The human CD3 ${varepsilon}$ -transfected clones were surface biotinylated and immunoprecipitated with Leu4 from Brij96 detergent lysates. The immunoprecipitates were resolved by two-dimensional nonreducing/reducing SDS-PAGE and immunoblotted with streptavidin-peroxidase. The positions of human and murine TCR and CD3 chains are indicated.

Expression of TCR complexes containing the human CD3 ${varepsilon}$ ER retentionmutant was clearly lower in ${zeta}$ -deficient than in ${zeta}$ -expressing cells(Fig. 5). This might reflect the fact that incorporation ofCD3 ${zeta}$ is required to hide the di-leucine endocytosis signal inCD3 ${gamma}$ (27, 28). These results show that the TCR complex can beexported to the plasma membrane in the absence of CD3 ${zeta}$ when theCD3 ${varepsilon}$ ER retention signal is eliminated. Furthermore, the resultsconfirm that the CD3 ${varepsilon}$ ER retention signal prevents cell surfaceexpression of the incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ and ${alpha}$ ß ${delta}$ ${varepsilon}$ complexesand suggest that this signal becomes inoperative only upon completionof the last assembly step with the incorporation of CD3 ${zeta}$ .

Masking of the CD3 ${varepsilon}$ ER retention signal upon CD3 ${zeta}$ assembly is position dependent
A prediction of the stepwise model of ER retention signal annulmentis that silencing of a given ER retention signal must be positionspecific; e.g., if CD3 ${zeta}$ assembly overrides the ER retention signalin CD3 ${varepsilon}$ , this must occur in the context of the specific topologicalposition of CD3 ${varepsilon}$ in the TCR complex. To evaluate this hypothesis,we constructed two new CD3 ${gamma}$ chimeras. In one of the chimeras,the cytoplasmic tail of CD3 ${gamma}$ was substituted by the tail of CD3 ${varepsilon}$ (Fig. 6 A, ${gamma}$ ${gamma}$ ${varepsilon}$ chimera). The other chimera was generated by appendingthe ER retention signal of CD3 ${varepsilon}$ at the COOH-terminal end of CD3 ${gamma}$ (Fig. 6 A, ${gamma}$ ret). Next, we examined whether assembly of the CD3 ${gamma}$ chimeras with the ER retention mutant of CD3 ${varepsilon}$ resulted in expressionof the ${gamma}$ ${varepsilon}$ dimer at the cell surface. As previously demonstrated(Fig. 3), assembly of wild-type CD3 ${gamma}$ with ${varepsilon}$ mut but not with wild-typeCD3 ${varepsilon}$ allowed transport of the ${varepsilon}$ ${gamma}$ dimer to the cell surface (Fig. 6B). In contrast, assembly of the CD3 ${gamma}$ chimeras ${gamma}$ ${gamma}$ ${varepsilon}$ and ${gamma}$ ret with ${varepsilon}$ mut prevented export of the ${varepsilon}$ ${gamma}$ dimer to the plasma membrane (Fig. 6B) and retained the dimer in the ER (Fig. S4, available athttp://www.jem.org/cgi/content/full/jem.20041133/DC1). Theseresults therefore show that abrogation of the ER retention signalsduring assembly of the ${varepsilon}$ ${gamma}$ dimer is dependent on both the sequenceof the cytoplasmic tail and the position of the ER retentionsignals within the dimer.

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Figure 6. Translocation of the CD3 ${varepsilon}$ ER retention signal to CD3 ${gamma}$ prevents ${varepsilon}$ ${gamma}$ dimer and TCR expression. (A) Scheme of CD3 ${gamma}$ chimeras where the CD3 ${gamma}$ domains are dotted. The presence of CD3 ${varepsilon}$ -derived sequences (the whole cytoplasmic tail in ${gamma}$ ${gamma}$ ${varepsilon}$ or the last 15 amino acids in ${gamma}$ ret) is indicated with black boxes. The three constructs were HA tagged at their NH₂ terminus. (B) Abrogation of the cytoplasmic ER retention signal in CD3 ${gamma}$ is position dependent. COS cells were transfected with combinations of either wild-type CD3 ${varepsilon}$ or the ER retention mutant ${varepsilon}$ mut and the indicated CD3 ${gamma}$ chimeras. Surface expression of the ${varepsilon}$ ${gamma}$ dimer was analyzed by two-color flow cytometry with anti-HA and anti-CD3 dimer (Leu4) antibodies in nonpermeabilized cells. Intracellular expression of the ${varepsilon}$ ${gamma}$ dimer was assessed by two-color flow cytometry of detergent-permeabilized cells (not depicted). The percentage of ${varepsilon}$ ${gamma}$ dimer-positive cells is indicated in the corresponding quadrants. (C) Abrogation of the CD3 ${varepsilon}$ ER retention signal upon CD3 ${zeta}$ assembly is position dependent. Jurkat CD3 ${gamma}$ ^– R3.25 cells were stably transfected with the indicated CD3 ${gamma}$ constructs, and geneticin-resistant clones were analyzed for TCR expression by double color flow cytometry with anti-HA and anti-CD3 (Leu 4) antibodies. The seven clones with the highest TCR expression for each construct are represented at the bottom. Two-color flow cytometry histograms for the clones with highest TCR expression are shown at the top. The total number of clones analyzed was 42 for the wild-type CD3 ${gamma}$ construct, 14 for the ${gamma}$ ret construct, and 48 for the ${gamma}$ ${gamma}$ ${varepsilon}$ construct. NT, nontransfected.

To extend these results to the full TCR complex, a CD3 ${gamma}$ ^–mutant of Jurkat was transfected with wild-type CD3 ${gamma}$ or withthe ${gamma}$ ${gamma}$ ${varepsilon}$ or ${gamma}$ ret chimeras, and stable clones were selected. Transfectionof wild-type CD3 ${gamma}$ but not the ${gamma}$ ${gamma}$ ${varepsilon}$ or ${gamma}$ ret chimeras reconstitutedthe surface expression of the TCR complex at high levels (Fig. 6C). These results show that if the CD3 ${varepsilon}$ ER retention signalis misplaced (either at the position of the CD3 ${gamma}$ tail or at thetip of CD3 ${gamma}$ ), CD3 ${zeta}$ assembly can no longer silence it.

Discussion

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In this study, we have tried to better understand the mechanismsthat regulate expression of TCR–CD3 complexes at the cellsurface and prevent nonassembled subunits and incomplete complexesfrom reaching or remaining in the plasma membrane. We foundthat removal of the CD3 ${varepsilon}$ ER retention signal is sufficient topermit expression of ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers at the surface of transfectedCOS cells. Indeed, even though CD3 ${gamma}$ contains multiple ER retentionsignals, these signals all become inoperative upon assemblywith CD3 ${varepsilon}$ . Furthermore, our results show that the absence ofthe CD3 ${varepsilon}$ ER retention signal is sufficient to allow the expressionof incomplete TCR complexes in the plasma membrane, even whenlacking CD3 ${zeta}$ .

Dual regulation through ER retention signals and proteasome-dependentdegradation from the ER prevents TCR subunits from progressingthrough the secretory pathway (38, 39). ER retention signalshave been described in CD3 ${varepsilon}$ , TCR ${alpha}$ , TCRß, CD3 ${delta}$ , and CD3 ${gamma}$ (15, 20–22, and this study), and it could be consideredthat all ER retention signals are abrogated simultaneously whenthe full TCR complex is assembled. However, our findings indicatethat there is a hierarchy among retention signals such thatthey become overridden progressively as the TCR complex assembles.Hence, we propose a model for the export of the TCR complex(Fig. 7) in which the ER retention signals of CD3 ${gamma}$ , CD3 ${delta}$ , TCR ${alpha}$ ,and TCRß become progressively inoperative as theyassemble with CD3 ${varepsilon}$ . The ER retention signal in CD3 ${varepsilon}$ remains dominantin these complexes.

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Figure 7. Model of sequential inactivation of TCR retention signals. Surface expression of free CD3 ${varepsilon}$ is prevented by a single ER retention signal (triangle), whereas expression of free CD3 ${gamma}$ is prevented by several ER retention signals (triangles) and a di-leucine endocytosis signal (circle). CD3 ${delta}$ may contain at least one cytoplasmic ER retention signal similar to those of CD3 ${gamma}$ and CD3 ${varepsilon}$ (triangle) and a di-leucine endocytosis signal (circle). Upon assembly of ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers, the ER retention determinants of CD3 ${gamma}$ and CD3 ${delta}$ are overridden, but surface expression of the ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers is prevented by the CD3 ${varepsilon}$ ER retention signal that remains functional. The endocytosis signals in CD3 ${gamma}$ (and probably CD3 ${delta}$ ) remain active in the ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers and are responsible for the internalization and removal of the small amounts of dimer that somehow reach the cell membrane on their own. TCR ${alpha}$ and TCRß contain additional ER retention determinants, but these do not seem to be operative in the ${alpha}$ ß ${gamma}$ ${varepsilon}$ (and probably ${alpha}$ ß ${delta}$ ${varepsilon}$ ) complex. Only after assembly of CD3 ${zeta}$ does the CD3 ${varepsilon}$ ER retention signal become nonfunctional, thus allowing the full TCR–CD3 complex to reach the plasma membrane. The stability of the full complex on the cell surface is also increased because the CD3 ${gamma}$ and CD3 ${delta}$ endocytotic signals are inactive. Removing both the CD3 ${varepsilon}$ ER retention signal and the CD3 ${gamma}$ endocytotic signal artificially increases surface expression of free ${varepsilon}$ ${gamma}$ dimers and incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complexes.

When is the ER retention signal in CD3 ${varepsilon}$ overridden? We postulatethat this takes place after association of ${zeta}$ , which has beenlong known to be the last step in assembly (6–8). Thisidea was not confirmed by our reconstitution studies in COScells, because efficient cell surface expression of the ${alpha}$ ß ${gamma}$ ${varepsilon}$ ${zeta}$ complex with wild-type CD3 ${varepsilon}$ was not observed. This might indicatethat CD3 ${delta}$ is mandatory for surface expression. However, our transfectionexperiments (not depicted) and the results of Kappes and Tonegawa(35) suggest that this is not the case. Moreover, transfectionof all TCR subunits in non–T cells is sufficient to detectthe full TCR complex at the cell surface (35, 40). This discrepancymight be explained by the greater sensitivity of radio iodination(40) compared with the flow cytometry used here, or by the factthat the transfected population underwent selection for highTCR expression (35). However, the poor efficiency of ER exportand the weak surface expression of the wild-type CD3 ${varepsilon}$ -containing ${alpha}$ ß ${gamma}$ ${varepsilon}$ ${zeta}$ complex might be better explained by the inefficientassembly of CD3 ${zeta}$ into the complex. Nevertheless, the resultsin COS cells and the model (Fig. 7) have been validated in ${zeta}$ -expressingand ${zeta}$ -deficient murine T cells transfected with human CD3 ${varepsilon}$ (Fig. 5).Human wild-type CD3 ${varepsilon}$ is targeted to the plasma membrane withinthe TCR complex only after assembly of CD3 ${zeta}$ , whereas the humanCD3 ${varepsilon}$ ER retention mutant can reach the membrane with and withoutCD3 ${zeta}$ . Studies in CD3 ${zeta}$ -deficient mice and cell lines show thatTCR–CD3 surface expression is extremely low in the absenceof this subunit (34, 41). Accordingly, our results show thatthe CD3 ${varepsilon}$ ER retention signal remains functional in the incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex, preventing cell surface expression. Theseresults also indicate that the orderly inactivation of intracellularretention signals serves to not only prevent surface expressionof the CD3 dimer (or TCR dimer), but also that of TCR–CD3complexes lacking CD3 ${zeta}$ .

What then is the mechanism that overrides CD3 ${varepsilon}$ 's ER retentionsignal upon assembly of ${zeta}$ ? It has been proposed that the cytoplasmictail of CD3 ${zeta}$ hides the otherwise exposed di-leucine endocytosismotif in CD3 ${gamma}$ by steric hindrance (28). Indeed, in ${zeta}$ -deficientcells it has recently been demonstrated that the TCR is morerapidly internalized and that expression of CD3 ${zeta}$ , or a CD3 ${zeta}$ chimerawith its cytoplasmic tail partially replaced by a foreign sequence,restores normal TCR internalization (27). Steric masking ofthe dilysine ER retention motif in the ${alpha}$ chain of the heterodimerichigh affinity receptor for immunoglobulin E (Fc ${varepsilon}$ RI) upon assemblywith the ${gamma}$ chain has been proposed to regulate plasma membranetargeting (2). Similarly, steric hindrance by the cytoplasmictail of CD3 ${zeta}$ could be responsible for annulling the CD3 ${varepsilon}$ ER retentionsignal, although other mechanisms involving CD3 ${zeta}$ -dependent rearrangementsof the TCR complex cannot be excluded. Interestingly, the ${gamma}$ chainof Fc ${varepsilon}$ RI and CD3 ${zeta}$ are structural and functionally related, andindeed, the Fc ${varepsilon}$ RI ${gamma}$ chain can take over the role of CD3 ${zeta}$ in TCRassembly in ${zeta}$ ^–/– mice (42–44). These resultssuggest a common mechanism underlying ER retention of immunereceptor complexes by components of the CD3 ${zeta}$ family. In any case,masking of the CD3 ${varepsilon}$ ER retention signal by CD3 ${zeta}$ assembly is positiondependent. Thus, either replacement of the cytoplasmic tailof CD3 ${gamma}$ by CD3 ${varepsilon}$ or apposition of an extra CD3 ${varepsilon}$ ER retention signalto the COOH-terminal end of CD3 ${gamma}$ prevents surface expressionof the full TCR complex (Fig. 6).

We have shown that the di-leucine endocytosis signal of CD3 ${gamma}$ ,together with the ER retention signal in CD3 ${varepsilon}$ , is also importantto reduce the expression of the ${varepsilon}$ ${gamma}$ dimer on the cell surface.Thus, high level expression of the ${varepsilon}$ ${gamma}$ (and by extension ${varepsilon}$ ${delta}$ ) dimeron the cell surface is prevented by impairing its export fromthe ER–Golgi and by stimulating the rapid endocytosisof dimers from the cell surface. This regulation of CD3 dimerand free CD3 subunit expression is required to prevent ligand-independenttriggering of signaling cascades. It has been shown that smallamounts of ${varepsilon}$ ${gamma}$ and ${varepsilon}$ ${delta}$ dimers expressed on the surface of immaturethymocytes, also known as clonotypic-independent complexes,can promote thymic differentiation and proliferation upon cross-linkingwith anti-CD3 antibodies (45). One might ask what would be theconsequence of augmenting the expression of CD3 dimers at thecell surface on thymic maturation. Studies in which a TCRßtransgene that lacks the variable region (46), or even all extracellulardomains (47), was expressed in MHC class I– and II–deficientmice indicate that the pre-TCR function is independent of ligandrecognition. The pre-TCR could therefore serve merely as a platformto express sufficiently high levels of the CD3 dimers at thecell surface to initiate ligand-independent signaling. Assemblyof the CD3 dimers with TCRß, pT ${alpha}$ , and CD3 ${zeta}$ must overridethe CD3 ${varepsilon}$ ER retention signal as well as those in TCRß(21) and pT ${alpha}$ (48). In this regard, it should be noted that theaddition of an extra ER retention signal to TCRß abolishespre-TCR function (49). These results suggest that the pre-TCRmust be expressed on the cell surface to carry out its signalingrole. Furthermore, unlike the natural ER retention signals presentin the TCR and CD3 subunits, the artificial signal introducedin TCRß does not appear to be annulled during assembly.

We have made an initial attempt to characterize the signalsthat regulate the intracellular retention of the CD3 ${gamma}$ chain.In accordance with previous observations (22), we found thatthe cytoplasmic tail of CD3 ${gamma}$ contains an ER retention signalat the COOH terminus. Although this sequence is reminiscentof the double arginine ER retention signal in type II membraneproteins (18, 19), we have discovered that only one of the twoarginines in CD3 ${gamma}$ is important for ER retention. Thus, the cytoplasmicCD3 ${gamma}$ ER retention signal better resembles that of CD3 ${varepsilon}$ , whichcontains only one important basic residue (arginine –3;references 15 and 16). In addition to the ER retention signal,the cytoplasmic tail of CD3 ${gamma}$ contains a putative ER export sequenceof the DxE type (31) and a di-leucine endocytosis signal (22,50). However, CD3 ${gamma}$ also contains ER retention determinants inits extracellular and transmembrane domains that have yet tobe characterized. These extracellular and transmembrane retentiondeterminants in CD3 ${gamma}$ could represent distinct sequence motifsor an unfolded state of the protein. In any case, it appearsthat in contrast to CD3 ${varepsilon}$ , the retention of free CD3 ${gamma}$ is regulatedby multiple signals.

In conclusion, the results presented here suggest that the TCR–CD3complex is endowed with a complicated system of intracellularretention signals that become overridden in a stepwise fashionas assembly proceeds. Assembly is regulated in such a way thatall intermediates have at least one functional retention signal.This system guarantees that only a full signaling-competentTCR–CD3 complex is expressed at the cell surface.

MATERIALS AND METHODS

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Cells
COS-7 cells were obtained from American Type Culture Collection(ATCC) and grown in DMEM plus 5% FBS (Sigma-Aldrich). The humanNK cell line YT was provided by M. López-Botet (UniversidadPompeu-Fabra, Barcelona, Spain), the murine 2B4 T cell hybridomawas from the ATCC, the CD3 ${zeta}$ -deficient mutant MA5.8 of 2B4 wasprovided by J. Ashwell (National Institutes of Health, Bethesda,MD), and the CD3 ${gamma}$ -deficient mutant R3.25 of Jurkat was providedby B. Rubin (CNRS, Toulouse, France). All cells were grown inRPMI medium plus 5% FBS.

Constructs.
All constructs were generated by PCR using human cDNAs as templates.PCR products were cloned into the pSR ${alpha}$ or pSR ${alpha}$ -HA (unpublisheddata) vectors. The 44 ${gamma}$ chimera is composed of the extracellularand the transmembrane domains of CD4 (finishing in positionV₃₉₅ of the mature polypeptide) fused to the complete intracellulardomain of CD3 ${gamma}$ (from position A₁₁₅ of the mature polypeptide).44 ${gamma}$ ${Delta}$ 1 to 44 ${gamma}$ ${Delta}$ 5 constructs have a stop codon at positions 157, 152,148, 141, and 121, respectively, of the mature human CD3 ${gamma}$ protein.Truncated CD3 ${gamma}$ ( ${gamma}$ tr) contains only the first two amino acids ofthe cytoplasmic tail. Wild-type human CD3 ${varepsilon}$ and the CD3 ${varepsilon}$ mutantlacking the last five COOH-terminal amino acids ( ${varepsilon}$ mut) have beendescribed (15, 51). Point mutants were generated by introducingthe mutation encoding for alanine in the positions 131, 158,159, and 160 of the mature human CD3 ${gamma}$ protein using 44 ${gamma}$ (44 ${gamma}$ _L131A,44 ${gamma}$ _L131A/N160A, 44 ${gamma}$ _L131A/R159A, and 44 ${gamma}$ _L131A/R158A) or CD3 ${gamma}$ ( ${gamma}$ _L131A, ${gamma}$ _R158A, and ${gamma}$ _L131A/R158A) as template. The 4 ${gamma}$ 4, ${gamma}$ 44, and ${gamma}$ ${gamma}$ ${varepsilon}$ constructswere created as isolated fragments by PCR, cloned into the intermediatevector pGEM-7Zf(+), and the chimeric cDNAs were subcloned intothe pSR ${alpha}$ -HA vector. The ${gamma}$ ret construct was created by PCR usinga 3' primer encoding for the last COOH-terminal 15 amino acidsof human CD3 ${varepsilon}$ (KGQRDLYSGLNQRRI) appended to the last amino acidof CD3 ${gamma}$ , and the PCR product was cloned into the pSR ${alpha}$ -HA vector.

Antibodies
The mAb anti–human SP34 that recognizes the CD3 ${varepsilon}$ extracellulardomain, the mAb anti–human CD3 UCHT1, the mAb anti–humanCD4 HP2/6, and the mAb anti–Cß Jovi.1 were providedby C. Terhorst (Beth Israel Deaconess Hospital, Boston, MA),P. Beverley (The Edward Jenner Institute for Vaccine Research,Berkshire, UK), F. Sánchez-Madrid (Hospital de la Princesa,Madrid, Spain), and M. Owen (CRUK, London, UK), respectively.The anti-CD3 ${zeta}$ antiserum 448 has been described (5). The followingmAbs were purchased as indicated: anti-HA epitope 12CA5 (RocheDiagnostics), anti-murine TCRß H57-597 and anti–humanCD3 Leu4 (BD Biosciences), and anti–human CD3 ${varepsilon}$ SK7 (StemCellTechnologies Inc.). All secondary fluorochrome-labeled antibodieswere purchased from BD Biosciences.

Cell transfections
COS cells were transiently transfected as described previously(32), and stable transfectants of YT, 2B4, MA5.8, and R3.25cells were generated by electroporation and selection in geneticin.

Flow cytometry
24 h after transfection, COS cells were detached from the platewith 0.02% EDTA in PBS and divided into two aliquots for surfaceand intracellular staining. For intracellular staining, cellswere first fixed with 2% paraformaldehyde in PBS for 20 minat 4°C and then permeabilized with 0.1% saponin in PBS at4°C for 1 h. Permeabilized and nonpermeabilized cells wereincubated with 4 µg/ml of the appropriate mAb for 30 minat 4°C and then with a secondary FITC- or PE-labeled antibody.For two-color staining, directly labeled antibodies were used.Surface expression is indicated as a percentage, as mean fluorescenceintensity (MFI), or by multiplying both parameters.

Confocal microscopy
Upon transfection, COS cells were plated on glass coverslips,fixed in paraformaldehyde at room temperature 24 h later, andthen permeabilized with saponin as described above. The coverslipswere mounted in Mowiol and examined with a confocal microscope(Radiance 2000; BioRad Laboratories).

Cell labeling and immunoprecipitation
48 h after transfection, COS cells were labeled with ³⁵S-methioninefor 15 min and then chased for different times in standard mediumbefore lysing with 1% NP-40 lysis buffer (150 mM NaCl, 20 mMTris-HCl, pH 7.8, 10 mM iodoacetamide, 1 mM PMSF, 1 µg/mlaprotinin, and 1 µg/ml leupeptin). Postnuclear lysateswere immunoprecipitated with an anti-CD4 antibody, and the immunoprecipitateswere resuspended in endo-H buffer (50 mM sodium citrate, pH5.5, 0.1% SDS, 1 mM PMSF, 1 µg/ml aprotinin, and 1 µg/mlleupeptin) before digesting half of the sample with endo-H.The samples were resolved by SDS-PAGE and analyzed by autoradiography.

For surface biotinylation, 50 x 10⁶ MA5.8 and 2B4 were incubatedwith 0.5 mg/ml sulfo-NHS-biotin (Pierce Chemical Co.) in PBSsupplemented with 0.1 mM CaCl₂ and 1 mM MgCl₂ for 45 min onice. After washing, surface complexes were recovered by incubatingthe labeled intact cells with human anti-CD3 antibody Leu4 beforelysis. Protein G was added and immunoprecipitates were subjectedto two-dimensional SDS-PAGE (first dimension under nonreducingand second dimension under reducing conditions), immunotransferredto a nitrocellulose membrane, hybridized with streptavidin horseradishperoxidase (Southern Biotechnology Associates, Inc.), and developedby ECL (Bio-Rad Laboratories).

Online supplemental material
Fig. S1 shows intracellular distribution of 44 ${gamma}$ deletional mutants.Fig. S2 shows intracellular distribution of the 44 ${gamma}$ point mutants.In Fig. S3, the ER retention signal in CD3 ${varepsilon}$ and the di-leucineendocytosis signal in CD3 ${gamma}$ both regulate surface expression ofthe incomplete ${alpha}$ ß ${gamma}$ ${varepsilon}$ complex. Fig. S4 illustrates theintracellular distribution of ${varepsilon}$ ${gamma}$ dimers. Figs. S1–S4 areavailable at http://www.jem.org/cgi/content/full/jem.20041133/DC1.

Acknowledgments

We are indebted to Imo Akpan, Miguel Alonso, Hisse van Santen,Mark Sefton, and Gabrielle Siegers for critical reading of themanuscript.

This work was supported by grants SAF2002-03589 from CICYT,08.3/0030.1/2001 from the Comunidad de Madrid, and by fundsfrom the Fundación Ramón Areces to the Centrode Biología Molecular.

The authors have no conflicting financial interests.

Submitted: 7 June 2004
Accepted: 23 December 2004

References

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Abstract
Results
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References

Margeta-Mitrovic, M. 2002. Assembly-dependent trafficking assays in the detection of receptor-receptor interactions. Methods. 27:311–317.[CrossRef][Medline]

Letourneur, F., S. Hennecke, C. Demolliere, and P. Cosson. 1995. Steric masking of a dilysine endoplasmic reticulum retention motif during assembly of the human high affinity receptor for immunoglobulin E. J. Cell Biol. 129:971–978.[Abstract/Free Full Text]

Alarcon, B., B. Berkhout, J. Breitmeyer, and C. Terhorst. 1988. Assembly of the human T cell receptor-CD3 complex takes place in the endoplasmic reticulum and involves intermediary complexes between the CD3-gamma.delta.epsilon core and single T cell receptor alpha or beta chains. J. Biol. Chem. 263:2953–2961.[Abstract/Free Full Text]

Koning, F., W.L. Maloy, and J.E. Coligan. 1990. The implications of subunit interactions for the structure of the T cell receptor-CD3 complex. Eur. J. Immunol. 20:299–305.[Medline]

San Jose, E., A.G. Sahuquillo, R. Bragado, and B. Alarcon. 1998. Assembly of the TCR/CD3 complex: CD3 epsilon/delta and CD3 epsilon/gamma dimers associate indistinctly with both TCR alpha and TCR beta chains. Evidence for a double TCR heterodimer model. Eur. J. Immunol. 28:12–21.[CrossRef][Medline]

Minami, Y., A.M. Weissman, L.E. Samelson, and