A role for the cytoplasmic tail of the pre-T cell receptor (TCR) alpha chain in promoting constitutive internalization and degradation of the pre-TCR

Engagement of the alpha beta T cell receptor (TCR) by its ligand results in the down-modulation of TCR cell surface expression, which is thought to be a central event in T cell activation. On the other hand, pre-TCR signaling is a key process in alpha beta T cell development, which appears to proceed in a constitutive and ligand-independent manner. Here, comparative analyses on the dynamics of pre-TCR and TCR cell surface expression show that unligated pre-TCR complexes expressed on human pre-T cells behave as engaged TCR complexes, i.e. they are rapidly internalized and degraded in lysosomes and proteasomes but do not recycle back to the cell surface. Thus, pre-TCR down-regulation takes place constitutively without the need for extracellular ligation. By using TCR alpha/p Tau alpha chain chimeras, we demonstrate that prevention of recycling and induction of degradation are unique pre-TCR properties conferred by the cytoplasmic domain of the pT alpha chain. Finally, we show that pre-TCR internalization is a protein kinase C-independent process that involves the combination of src kinase-dependent and -independent pathways. These data suggest that constitutive pre-TCR down-modulation regulates pre-TCR surface expression levels and hence the extent of ligand-independent signaling through the pre-TCR.     

Characterization and expression of the human alpha beta T cell receptor by using a framework monoclonal antibody

A monoclonal antibody (mAb) with framework reactivity against the T cell receptor (TCR) alpha beta complex is characterized. The mAb, beta Framework 1 (beta F1) is capable of immunoprecipitating the TCR alpha beta complex from 125I-labeled human T cell tumors, immunocompetent T cell clones, and peripheral blood lymphocytes (PBL). beta F1 recognizes the separated TCR beta subunit in Western blotting. Because it does not bind to the surface of viable T cells but does react with the plasma membrane form of the TCR after treatment with membrane solubilizing agents, the beta F1 mAb reacts with a "hidden" determinant on the TCR beta subunit. After solubilization with 70% ethanol, the TCR alpha beta complex is shown to exist on greater than 92% of T3+ human PBL, whereas 2 to 8% of T3+ PBL do not react with the mAb. The beta F1 mAb demonstrates the existence of differently glycosylated surface 125I-labeled TCR alpha-chains (alpha, alpha', alpha") in association with a common TCR beta-chain on the HPB-MLT T cell leukemia. Reactivity of the beta F1 mAb on thymus tissue sections is similar to that of anti-Leu-4 (anti-T3). The beta F1 mAb should prove useful as a research tool for both the immunochemical characterization and isolation of virtually any alpha beta T cell receptor, whether from individual T cell clones or polyclonal populations of T lymphocytes. Recognition of T cell receptors in histologic tissue sections suggests that the beta F1 mAb may be useful in the clinical diagnosis of T cell lineage neoplasms. In failing to recognize all T3+ lymphocytes, it allows the identification of novel populations of T3+ lymphocytes that may express non-alpha, non-beta T cell receptors.     

T cell receptor delta gene organization and expression in normal and leukemic natural killer cells

In peripheral blood most NK activity is mediated by CD3- cells with large granular lymphocyte morphology which cannot be assigned to a specific hemopoietic lineage. In accordance with previous studies we have analyzed the organization of the TCR delta gene, which rearranges early in thymic ontogeny, in normal NK cells, and in granular lymphocytes proliferative disorders (GLPD), in an effort to further define their relationship to the T cell differentiation pathway and to identify a possible marker of clonality for CD3- GLPD. The alpha/delta locus was rearranged in five cases of CD3+ GLPD with a biallelic deletion of the C delta region, suggesting V-J alpha rearrangement, whereas CD3- GLPD and normal CD3- NK cells had the delta gene in germ-line configuration, but surprisingly expressed high levels of TCR delta-related mRNA. On the basis of this finding and of the presence of truncated TCR-beta and CD3-epsilon mRNA, we are led to speculate on a possible ontogenic relationship of NK cells to the T cell differentiation pathway at stages preceding TCR gene rearrangement.     

T cell receptor (TCR) beta chain homodimers on the surface of immature but not mature alpha, gamma, delta chain deficient T cell lines.

Transfected T cell receptor (TCR) beta chain genes are expressed as homodimers on the surface of immature (Sci/ET27F) but not on mature (58 alpha-beta-) T cell lines which lack TCR alpha, gamma and delta chains. The homodimer on Sci/ET27F cells is tightly bound to CD3 delta and CD3 epsilon while the association with CD3 gamma and CD3 zeta proteins is rather weak. Crosslinking of the TCR beta homodimers resulted in a strong and rapid calcium flux. In 58 alpha-beta- T cells the beta TCR chain could be easily visualized intracellularly but was not transported to the cell surface. The Scid cell lines considerably facilitate the molecular analysis of early differentiation events in the thymus which are likely to be regulated by the beta TCR homodimer.     

T cell differentiation model based on the expression of T cell receptor chains and genes--study in the human leukemia/lymphoma cell lines

A total of 33 human leukemia/lymphoma cell lines were classified into 4 groups with respect to the pattern of cell membrane (sm) expression of the CD3 and T cell receptor (TCR) molecules; (i) smCD3+TCR alpha beta (16 cell lines), (ii) smCD3+TCR beta delta (1 cell line), (iii) smCD3+TCR gamma delta (3 cell lines) amd (iv) smCD3-TCR- (13 cell lines), respectively. Using monoclonal antibodies (MoAbs) specific to CD3 (NU-T3), TCR alpha chain (alpha F1), TCR beta chain (beta F1), and TCR gamma chain (C gamma M1), respectively, cytoplasmic (cy) expression of these molecules was determined by immunofluorescence test. Expression of cyCD3 was present in all cell lines regardless of groups. In group (i), all 16 cell lines expressed both TCR alpha and beta chains. While only TCR beta chain was expressed in group (ii), TCR gamma chain was expressed in all 3 cell lines of group (iii). One (PEER) of the three in group (iii) expressed TCR beta chain as well. In group (iv), we found 8 cell lines with cyTCR alpha expression, 11 cell lines with cyTCR beta expression, and 10 cell lines with cyTCR gamma expression, respectively. For TCR genes, except 1 cell line all cell lines were found to present rearranged C beta gene and its mRNA, including all 3 TCR gamma/delta cell lines of group (iii). One of the TCR alpha beta cell lines exhibited rearranged C delta and J delta genes as well as its mRNA. Two cell lines of the 13 CD3-TCR- of group (iv) exhibited rearranged C delta and J delta and its mRNA. An NK-like activity and IL-2 production were induced in the TCR beta delta and gamma delta cell lines [group (ii) and (iii)] by treatment with PHA and PMA.     

A novel strategy for the generation of T cell lines lacking expression of endogenous alpha- and/or beta-chain T cell receptor genes

Mutant T cell lines that do not express the endogenous alpha- and/or beta-chain genes of the TCR were generated from the alpha beta TCR/CD3+ tumor cell line C6VL with a combination of classical mutagenesis methods and selection of somatic hybrid variants. This novel strategy obviated the need for repeated mutagenesis and screening of a large number of individual clones. The loss of either the alpha- or the beta-chain expression in the mutant cells was associated with the loss of surface TCR/CD3 complex, which could be rescued by the transfection of appropriate exogenous alpha- and/or beta-chain gene constructs. Because these cells express a single TCR molecule on the cell surface, they are useful for the study of the assembly and function of the alpha beta TCR. This strategy is also generally applicable for the generation of homozygous mutant cell lines lacking other gene products.     

Six chains of the human T cell antigen receptor.CD3 complex are necessary and sufficient for processing the receptor heterodimer to the cell surface

The T cell antigen receptor (TCR) plays a key role in the process of antigen recognition. It is a complex of at least seven peptide chains (alpha beta gamma delta epsilon zeta-zeta). It is found on the surface of mature T cells and functions in antigen binding in the presence of the major histocompatibility complex. It has been known for some time that physical associations between the CD3 proteins and the TCR chains are essential for efficient transport of either component to the surface of T cells. For example, T cells that lack either the alpha, beta, or delta chains synthesize partial complexes that are eventually degraded. cDNAs encoding the six chains of receptor have become available recently. We have used transfection techniques to generate a panel of Chinese hamster ovary cells that contain partial receptor complexes of known composition and also cells that express all six subunits of the TCR.CD3 complex. Cells in this panel were analyzed for the ability to form alpha-beta heterodimers and also an ability to transport the synthesized chains to the plasma membrane. These studies have allowed us to define the minimum requirements for TCR.CD3 expression on the cell surface.     

Developmental regulation of alpha beta T cell antigen receptor expression results from differential stability of nascent TCR alpha proteins within the endoplasmic reticulum of immature and mature T cells.

The alpha beta T cell antigen receptor (TCR) that is expressed on most T lymphocytes is a multisubunit transmembrane complex composed of at least six different proteins (alpha, beta, gamma, delta, epsilon and zeta) that are assembled in the endoplasmic reticulum (ER) and then transported to the plasma membrane. Expression of the TCR complex is quantitatively regulated during T cell development, with immature CD4+CD8+ thymocytes expressing only 10% of the number of surface alpha beta TCR complexes that are expressed on mature T cells. However, the molecular basis for low TCR expression in developing alpha beta T cells is unknown. In the present study we report the unexpected finding that assembly of nascent component chains into complete TCR alpha beta complexes is severely impaired in immature CD4+CD8+ thymocytes relative to their mature T cell progeny. In particular, the initial association of TCR alpha with TCR beta proteins, which occurs relatively efficiently in mature T cells, is markedly inefficient in immature CD4+CD8+ thymocytes, even for a matched pair of transgenic TCR alpha and TCR beta proteins. Inefficient formation of TCR alpha beta heterodimers in immature CD4+CD8+ thymocytes was found to result from the unique instability of nascent TCR alpha proteins within the ER of immature CD4+CD8+ thymocytes, with nascent TCR alpha proteins having a median survival time of only 15 min in CD4+CD8+ thymocytes, but > 75 min in mature T cells. Thus, these data demonstrate that stability of TCR alpha proteins within the ER is developmentally regulated and provide a molecular basis for quantitative differences in alpha beta TCR expression on immature and mature T cells. In addition, these results provide the first example of a receptor complex whose expression is quantitatively regulated during development by post-translational limitations on receptor assembly.     

CD3+4-8- alpha beta T cell population with biased T cell receptor V gene usage. Presence in bone marrow and possible involvement of IL-3 for their extrathymic development.

Analysis of TCR of a series of CD4-8- (double negative; DN) alpha beta T cell lines induced with IL-3 revealed that their V gene usage was biased for V alpha 4 and V beta 2. This has been confirmed in the primary short-term cultures. Thus, IL-3 induced the generation of DN alpha beta T cells with predominant V beta 2 gene expression from the CD4+/CD8+ T cell-depleted spleen or bone marrow (BM) cells of both normal and nude BALB/c mice within 10 days. It was further indicated that the V beta 2+ beta-chain genes contained few junctional N regions in both IL-3-induced primary DN alpha beta T cells and continuous lines. Search for the in vivo counterpart of in vitro IL-3-induced DN alpha beta T cells revealed that BM, but not spleens, of normal BALB/c and B6 mice did contain a significant proportion of DN alpha beta T cells, and that the majority of them expressed V beta 2+ beta-chain genes with few junctional N regions. The presence of V beta 2+ DN alpha beta T cells was similarly observed in the BM of BALB/c nude mice, but their proportion varied markedly among various strains of mice, which was not linked to H-2 haplotypes. The results indicated that V beta 2+ DN alpha beta T cells in the BM represented one of the thymus-independent T cell populations, whose development was under the major histocompatibility Ag complex-unlinked genetic control. TCR of these T cells were shown to be functional as judged by the proliferative response to anti-V beta 2 antibody. Taken together, present results suggested that IL-3 could induce differentiation and/or proliferation of DN alpha beta T cells with uniquely limited repertoire, which existed preferentially in BM in vivo, and implied the possible involvement of extrathymic endogenous ligands as a positive selection force.     

CD8-independent tumor cell recognition is a property of the T cell receptor and not the T cell

The CD8 coreceptor enhances T cell function by stabilizing the TCR/peptide/MHC complex and/or increasing T cell avidity via interactions with the intracellular kinases Lck and LAT. We previously reported a CD4(+) T cell (TIL 1383I), which recognizes the tumor-associated Ag tyrosinase in the context of HLA-A2. To determine whether CD8 independent tumor cell recognition is a property of the TCR, we used retroviral transduction to express the TIL 1383I TCR in the CD8(-) murine lymphoma, 58 alpha(-)/beta(-). Immunofluorescent staining of TCR-transduced cells with human TCR V beta subfamily-specific and mouse CD3-specific Abs confirmed surface expression of the transferred TCR and coexpression of mouse CD3. Transduced effector cells secreted significant amounts of IL-2 following Ag presentation by tyrosinase peptide-pulsed T2 cells as well as stimulation with HLA-A2(+) melanoma lines compared with T2 cells alone or HLA-A2(-) melanoma cells. Further analysis of TCR-transduced clones demonstrated a correlation between T cell avidity and cell surface expression of the TCR. Therefore, the TIL 1383I TCR has sufficient affinity to mediate recognition of the physiologic levels of Ag expressed by tumor cells in the absence of CD8 expression.     

TCR beta and TCR alpha gene enhancers confer tissue- and stage-specificity on V(D)J recombination events.

We describe transgenic mice carrying germline variable gene segments associated with either the T cell receptor (TCR) beta or alpha gene enhancers (E beta or E alpha). Transgenic constructs underwent high rates of site-specific rearrangements predominantly in T cells from independent mice. Rearrangements of the E beta-containing transgenes began at different stages of T cell differentiation in embryonic and adult thymus than did the E alpha-containing ones, with a pattern superimposable upon the patterns of TCR beta or TCR alpha gene expression, respectively. We demonstrate that sequences within the TCR beta and TCR alpha gene enhancers confer tissue- and stage-specificity upon the V(D)J recombination events affecting adjacent gene segments. The patterns of transgene expression also gave information on developmental events and lineage relationships (gamma delta versus alpha beta) during T cell development.     

Novel function for intestinal intraepithelial lymphocytes. Murine CD3+, gamma/delta TCR+ T cells produce IFN-gamma and IL-5.

Intestinal intraepithelial lymphocytes (IEL) from mice are greater than 80% CD3+ T cells and could be separated into four subsets according to expression of CD4 and CD8. In our studies designed to assess the functions of IEL, namely, cytokine production, it was important to initially characterize the various subsets of T cells that reside in IEL. The major subset was CD4-, CD8+ (75% of CD3+ T cells), which contained approximately 45 to 65% gamma/delta TCR+ and 35 to 45% alpha/beta TCR+ T cells. Approximately 7.5% of IEL T cells were CD4-, CD8- (double negative) and gamma/delta+ population. On the other hand, CD4+, CD8+ (double positive) and CD4+, CD8- fractions represented 10% and 7.5% of CD3+ T cells, respectively, which were all alpha/beta TCR+. Inasmuch as CD3+, CD4-, CD8+ T cells are a major subset of IEL which contain both gamma/delta TCR or alpha/beta TCR-bearing cells, the present study was focused on the capability of this subset of IEL T cells to produce the cytokines IFN-gamma and IL-5. Both gamma/delta TCR+ and alpha/beta TCR+ IEL spontaneously produced IFN-gamma and IL-5, although higher frequencies of cytokine spot-forming cells were associated with the alpha/beta TCR+ subset. Approximately 30% of CD8+, gamma/delta TCR+ cells produced both cytokines, whereas approximately 90% of alpha/beta TCR+ T cells produced either IFN-gamma or IL-5. Both gamma/delta TCR+ and alpha/beta TCR+ IEL possessed large quantities of cytokine-specific mRNA, clearly showing that these IEL were programmed for cytokine production. When IEL were activated with anti-gamma/delta or anti-CD8 antibodies, higher numbers of IFN-gamma and IL-5 spot-forming cells were noted. The present study has provided direct evidence that a major function of IEL involves cytokine production, and this is the first evidence that gamma/delta TCR+ cells in IEL possess the capability of producing both IL-5 and IFN-gamma.     

T cell receptor expression can switch on and off at a posttranslational level.

The human T acute lymphocytic leukemia cell line, SUP-T13, is a mosaic of TCR/CD3+ and TCR/CD3- cells. Individual SUP-T13 cells can spontaneously switch on and off surface TCR/CD3 expression. This switching was demonstrated by culturing and analysis of single cell clones that were TCR/CD3+ or TCR/CD3-. The rate of switching is about 10(-2)/cell per generation in either direction. This is too high to be due to a spontaneous mutation event. Furthermore, switched cells can revert at similar rates, as demonstrated by repeated cloning and reanalysis. This makes it likely that a regulatory change is responsible for switching. In support of this, all known TCR/CD3 proteins are found intracellularly in TCR/CD3- cells, and they associate with each other as in TCR/CD3+ cells. Furthermore, no structural abnormalities of the TCR/CD3 chains can be seen in TCR/CD3- cells using two-dimensional electrophoresis. However, in these cells, the chains accumulate in great excess intracellularly. This accumulation is specific to the TCR/CD3 complex, as other glycoproteins are still expressed normally on the cell surface. Thus, there is regulation of TCR expression at a posttranslational level. These TCR/CD3- cells may lead to the identification of novel protein(s) involved in glycosylating, processing, or transporting the TCR/CD3 complex. Potential loss of TCR/CD3 expression may also limit the feasibility of TCR-based therapies for T cell leukemias.