Developmentally regulated rearrangement and expression of genes encoding the T cell receptor-T3 complex

Human leukemic cells corresponding to the earliest identifiable stages of intrathymic T cell differentiation lack cell surface expression of the T cell receptor(TCR alpha/beta)-T3 complex but transcribe TCR beta mRNA from either germ-line configuration (1/13) or partially (DJ) or fully (VDJ) rearranged (12/13) genes. These cells do not produce TCR alpha mRNA, but do contain T3 delta and T3 epsilon mRNA and accumulate T3 polypeptides, primarily in the perinuclear envelope. Equivalent normal T cells isolated from thymus have a predominantly germ-line configuration of TCR beta but contain intracellular T3 proteins. T3 gene expression is therefore a very early event in T cell differentiation. TCR alpha chain production appears to be the limiting maturation-linked event in the transport, assembly, and cell surface membrane insertion of the TCR alpha/beta-T3 complex.     

Role of CD3 gamma in T cell receptor assembly

The T cell receptor (TCR) consists of the Ti alpha beta heterodimer and the associated CD3 gamma delta epsilon and zeta 2 chains. The structural relationships between the subunits of the TCR complex are still not fully known. In this study we examined the role of the extracellular (EC), transmembrane (TM), and cytoplasmic (CY) domain of CD3 gamma in assembly and cell surface expression of the complete TCR in human T cells. A computer model indicated that the EC domain of CD3 gamma folds as an Ig domain. Based on this model and on alignment studies, two potential interaction sites were predicted in the EC domain of CD3 gamma. Site-directed mutagenesis demonstrated that these sites play a crucial role in TCR assembly probably by binding to CD3 epsilon. Mutagenesis of N-linked glycosylation sites showed that glycosylation of CD3 gamma is not required for TCR assembly and expression. In contrast, treatment of T cells with tunicamycin suggested that N-linked glycosylation of CD3 delta is required for TCR assembly. Site-directed mutagenesis of the acidic amino acid in the TM domain of CD3 gamma demonstrated that this residue is involved in TCR assembly probably by binding to Ti beta. Deletion of the entire CY domain of CD3 gamma did not prevent assembly and expression of the TCR. In conclusion, this study demonstrated that specific TCR interaction sites exist in both the EC and TM domain of CD3 gamma. Furthermore, the study indicated that, in contrast to CD3 gamma, glycosylation of CD3 delta is required for TCR assembly and expression.     

The biosynthesis and assembly of T cell receptor alpha- and beta-chains with the CD3 complex

The biosynthesis, processing, and assembly of the TCR alpha- and beta-chains with each other and with the CD3 complex were investigated on both cell surface positive (TCR+CD3-) and negative (TCR-CD3-) cell lines. The results indicate that 1) in cell surface TCR-CD3- cell lines (MOLT 3, CCRF-CEM), TCR-beta, but not alpha-chains are present intracellularly. TCR-beta-CD3 complexes are readily found in these cell lines, but no evidence for final processing or cell surface expression of such incomplete TCR-CD3 complexes is observed. 2) In the cell surface TCR+CD3+ cell line HPB-ALL, both alpha- and beta-chains are present intracellularly. Whereas non-glycosylated forms of TCR-beta chain can be detected, only more mature forms of TCR alpha-chains are detected indicating that the alpha-chains are more rapidly glycosylated than the beta-chains. 3) The large majority of the intracellular alpha- and beta-chains is not disulfide linked and a small fraction of these is associated with CD3. 4) Only small amounts of the total intracellular TCR chains are found as CD3-associated disulfide-linked alpha beta-heterodimers. 5) Final processing of TCR chains for cell surface expression takes place after formation of these TCR-alpha beta-CD3 complexes. Thus, both the TCR alpha- and beta-chains are over-produced and only relatively small amounts of these chains form CD3-associated heterodimers that are processed for cell surface expression. Analogous results were obtained with a non-leukemic CTL clone. Based on these observations, a model for the biosynthesis and assembly of the TCR-CD3 complex is presented.     

Human postnatal CD4- CD8- CD3- thymic T cell precursors differentiate in vitro into T cell receptor delta-bearing cells

The signals required for activation and the differentiation of human triple negative postnatal thymocytes were studied in vitro. Highly purified populations of CD4-, CD8-, CD3- (triple negative) thymocytes were isolated by combined panning and preparative cell sorting and the ability of triple negative thymocytes to proliferate in response to various cytokines determined. Maximal triple negative proliferation was obtained using a mitogenic combination of CD2 antibodies and either rIL-2 or the phorbol ester, PMA. Long term growth (2 to 6 wk) of postnatal triple negative thymocytes was best achieved using CD2 antibodies and rIL-2. After in vitro culture with CD2 antibodies and rIL-2, triple negative thymocytes gave rise to TCR-delta+ cells beginning on day 2 of culture (approximately 15% CD3/TCR-delta+) reaching maximum (approximately 60% CD3/TCR-delta+) on day 7 with stable number of TCR-delta+ cells observed in vitro for up to 6 wk. Analysis of 30 clones of human postnatal triple negative thymocytes demonstrated 9 of 30 (30%) were TCR-delta+, beta F1-, essentially ruling out overgrowth of the triple negative population over time by a minor pool of contaminating TCR-delta+ cells. Thus, these studies have defined an in vitro culture system for human postnatal T cell precursors and demonstrated that precursors of human TCR-gamma delta+ T cells reside in the triple negative thymocyte pool.     

Failure to synthesize the T cell CD3-zeta chain: structure and function of a partial T cell receptor complex

The T cell antigen receptor is composed of two variable chains (alpha and beta, termed Ti), which confer ligand specificity, and five constant chains (gamma, delta, epsilon, zeta, and p21, collectively termed CD3) whose functions are poorly understood. To explore the roles of the individual CD3 components, an antigen-specific murine T cell hybridoma was chemically mutagenized and antigen-induced growth inhibition was used to select CD3/Ti expression variants. One variant produced all CD3/Ti components except CD3-zeta and was able to express small amounts of surface CD3/Ti. This variant failed to respond normally to either antigen or a mitogenic anti-Thy-1 antibody. Surprisingly, in the absence of CD3-zeta, direct cross-linking of the partial receptor induced both phosphatidylinositol hydrolysis and interleukin 2 production. These data indicate that CD3-zeta determines the normal intracellular fate of the T cell antigen receptor and is likely to play an important role in physiologically relevant transmembrane signaling.     

Somatic cell mapping of T-cell receptor CD3 complex and CD8 genes in cattle

Bovine genes encoding T-cell receptor, CD3, and CD8 molecules have been mapped to syntetic groups using bovine × rodent hybrid somatic cells. T-cell receptor and chains were assigned to bovine syntenic group U5, and the and genes were syntenic with each other and with markers on U13. CD3E and CD3D genes were syntenic with each other and located to bovine syntenic group U19. CD8 was most concordant with markers of syntenic group U16, although the concordancy was only 85% and the assignment must be regarded as tentative. The comparative gene maps of human chromosome 7, bovine syntenic group U13, and mouse chromosomes 6 and 13 suggest extensive evolutionary conservation.     

Transfection of dendritic cells with RNA induces CD4- and CD8-mediated T cell immunity against breast carcinomas and reveals the immunodominance of presented T cell epitopes

Transfection of dendritic cells (DC) with tumor-derived RNA has recently been shown to elicit tumor-specific CTL capable of recognizing and lysing a variety of tumor cells. In our study we analyzed the induction of HLA class I- and II-restricted T cell responses against MCF-7 breast cancer cells. Using this approach we were able to elicit CD4- and CD8-mediated antitumor responses. The CTL specifically lysed MCF-7 cells and DC electroporated with MCF-7 RNA, but spared control cell lines. The specificity of the cytotoxic activity was confirmed in cold target inhibition assays and using mAbs blocking HLA class I molecules. Interestingly, these polyclonal cytotoxic T cells recognized selectively two epitopes derived from the MUC1 and Her-2/neu tumor Ags. The induced Th cells were found to be entirely HLA class II restricted and showed a significant cross-reactivity to a renal cell carcinoma cell line, similar to the results obtained with cytotoxic T cells.     

A membrane-proximal tetracysteine motif contributes to assembly of CD3deltaepsilon and CD3gammaepsilon dimers with the T cell receptor

Assembly of the T cell receptor (TCR) with its dimeric signaling modules, CD3deltaepsilon, CD3gammaepsilon, and zetazeta, is organized by transmembrane (TM) interactions. Each of the three assembly steps requires formation of a three-helix interface involving one particular basic TCR TM residue and two acidic TM residues of the respective signaling dimer. The extracellular domains of CD3deltaepsilon and CD3gammaepsilon contribute to assembly, but TCR interaction sites on CD3 dimers have not been defined. The structures of the extracellular domains of CD3deltaepsilon and CD3gammaepsilon demonstrated parallel beta-strands ending at the first cysteine in the CXXCXEXXX motif present in the stalk segment of each CD3 chain. Mutation of the membrane-proximal cysteines impaired assembly of either CD3 dimer with TCR, and little complex was isolated when all four membrane-proximal cysteines were mutated to alanine. These mutations had, however, no discernable effect on CD3deltaepsilon or CD3gammaepsilon dimerization. CD3deltaepsilon assembled with a TCRalpha mutant that lacked both immunoglobulin domains, but shortening of the TCRalpha connecting peptide reduced assembly, consistent with membrane-proximal TCRalpha-CD3deltaepsilon interactions. Chelation of divalent cations did not affect assembly, indicating that coordination of a cation by the tetracysteine motif was not required. The membrane-proximal cysteines were within close proximity but only formed covalent CD3 dimers when one cysteine was mutated. The four cysteines may thus form two intrachain disulfide bonds integral to the secondary structure of CD3 stalk regions. The three-chain interaction theme first established for the TM domains thus extends into the membrane-proximal domains of TCRalpha-CD3deltaepsilon and TCRbeta-CD3gammaepsilon.     

Biochemical evidence for the presence of a single CD3delta and CD3gamma chain in the surface T cell receptor/CD3 complex

The T cell antigen receptor (TCR) consists of an alphabeta heterodimer and associated invariant CD3gamma, delta, epsilon, and zeta chains (TCR/CD3 complex). The general stoichiometry of the receptor complex, which is believed to be one molecule each of TCRalpha, TCRbeta, CD3gamma, and CD3delta and two molecules each of CD3epsilon and CD3zeta, is not clearly understood. Although it has been shown that there are two chains of CD3epsilon and CD3zeta, the stoichiometry of CD3gamma or CD3delta chains in the surface antigen receptor complex has not been determined. In the present study, transgenic mice expressing an altered form of mouse CD3delta and CD3gamma were employed to show that the surface TCR complexes contain one molecule each of CD3delta and CD3gamma. Thymocytes from wild type and CD3 chain transgenic mice on the appropriate knockout background were surface-biotinylated and immunoprecipitated using a specific antibody. The immunoprecipitates were resolved in two dimensions under nonreducing/reducing conditions to determine the stoichiometry of CD3delta and CD3gamma in the surface antigen receptor complex. Our data clearly show the presence of one molecule each of CD3delta and CD3gamma in the surface TCR/CD3 complex.     

A macromolecular structure favouring microtubule assembly in NGF-differentiated pheochromocytoma cells (PC12).

Cellular extracts derived from pheochromocytoma cells (PC12-) inhibit the assembly of calf brain tubulin, while those derived from nerve growth factor-differentiated cells (PC12+) do not display this effect. Incubation with RNase abolishes the inhibition by PC12- extracts and reveals the presence of an activating effect exerted by PC12+ extracts. Activation of microtubule assembly is enhanced when extracts are prepared from PC12+ cells exposed for 1 day to 1.0 microM taxol and is abolished when PC12+ extracts are: (a) prepared from cells incubated for 1 day with 1 microM colchicine, (b) treated with the non-ionic detergent Nonidet P-40 or (c) centrifuged at 100 000 g instead of 80 000 g. 2D gel electrophoresis of the proteins of the 100 000 g pellet responsible for the activating effect (referred to as 100 K g pellet) reveals the presence of 100 K, 88 K and 32 K proteins which are markedly enriched in PC12+ extracts. The 88 K protein is further enriched in taxol-treated cells and markedly reduced in the same cells incubated with colchicine. A correlation between the differential protein composition of the 100 K g pellets and their effect on microtubule formation is postulated.     

Enhanced expression of cell cycle regulatory genes in virus-specific memory CD8+ T cells

Unlike naive CD8+ T cells, antigen-experienced memory CD8+ T cells persist over time due to their unique ability to homeostatically proliferate. It was hypothesized that memory cells might differentially regulate the expression of genes that control the cell cycle to facilitate homeostatic proliferation. To test this, the expression levels of 96 different cell cycle regulatory genes were compared between transgenic naive and memory CD8+ T cells that specifically recognize the GP33-41 epitope of lymphocytic choriomeningitis virus (LCMV). It was discovered that relative to naive cells, memory cells overexpress several important genes that control the transition between G(1) and S phase. Some of these genes include those encoding cyclins D3, D2, B1, C, and H, cyclin-dependent kinases (cdk's) 4 and 6, the cdk inhibitors p16, p15, and p18, and other genes involved in protein degradation and DNA replication. Importantly, these differences were observed both in total populations of LCMV-specific naive and memory CD8+ cells and in LCMV-specific CD8+ T-cell populations that were in the G(1) phase of the cell cycle only. In addition, the expression differences between naive and memory cells were exaggerated following antigenic stimulation. The fact that memory cells are precharged with several of the major factors that are necessary for the G(1)- to-S-phase transition suggests they may require a lower threshold of stimulation to enter the cell cycle.     

CD45-protein tyrosine phosphatase cross-linking inhibits T cell receptor CD3-mediated activation in human T cells

Activation of peripheral blood T cells, and the leukemic T cell line Jurkat, as measured by mobilization of intracellular calcium, by an anti-TCR antibody is blocked by mAb (T191) to the leukocyte common Ag (CD45). T191 also blocked down-regulation of the CD3-TCR complex induced by an anti-CD3 mAb. Vanadate, a phosphotyrosine phosphatase inhibitor, partially blocks the effect of T191 and restored mobilization of intracellular calcium. Assays of the immunoprecipitates of T191 and CD45 from both Jurkat-BM1 and peripheral T cells showed that the immune complexes had intrinsic phosphatase activity. A parallel immunoprecipitate using a mAb (4-10) against HLA class I showed no such activity. Further analysis of the T191 immunocomplex revealed activity against phosphotyrosine, p-nitrophenylphosphate, and [32P-poly-glu-tyr, but not against phosphoserine. Phosphatase activity was inhibited by Vanadate, but not by Zn2+ or F-. These results show that CD45 is a phosphotyrosine phosphatase, and strongly suggest that tyrosine phosphorylation/dephosphorylation is critically involved in activation of T cells through the TCR-CD3 complex.     

The expression of T cell receptor-associated proteins during T cell ontogeny in man

The expression of TCR-associated molecules was examined in human fetal and postnatal tissues. From gestational wk 7 onward in the fetal liver, putative prothymocytes have been identified with cytoplasmic CD3 positivity (cCD3+). These immature cells are TdT- and do not express membrane CD3 (mCD3-) or TCR beta identified by beta F1, but show CD7 and CD45 positivity without CD1, CD2, CD5, CD4, CD8, CD10, and class II Ag. Their high proliferative activity is indicated by greater than 85% Ki67 positivity. After the 10th wk, beta F1+, mCD3+ cells also appear in the liver and these are mostly Ki67- but no TCR gamma delta-bearing cells can be identified at such an early stage of extrathymic development. In the mCD3- TdT-fetal thymus (10 1/2 to 18th wk) cCD3+, mCD3- CD1-blasts proliferate (Ki67+) and lack TCR-beta or TCR-gamma delta. The TdT-, CD1+ cortical thymocytes develop into TCR-beta + and WT31-positive (TCR-alpha beta +) cells. Subsequently TdT-positive thymocytes become detectable around 19 to 20 wk, and in such glands the peak of proliferative activity is seen among TdT+, cCD3+ cells which appear to acquire, in a regular sequence, cytoplasmic beta F1 (TCR-beta), mCD3, and TCR-alpha beta (WT31 positivity) together with the loss of TdT and Ki67 positivity. A newly described transitional population of cells is TdT-, beta F1+ but exhibits no detectable WT31 positivity. These cells correspond to the CD1+, mCD3+ thymocytes and are probably the targets of thymic selection. The cells of the TCR-gamma delta lineage, detected by mAb TCR-delta-1 and delta TCS1, are rare (0.02 to 0.5%) among thymocytes from gestational wk 10 1/2 onward through the whole span of thymic development, but these cells include a proportion (18 to 59%) of cells expressing CD1 Ag, suggesting that these TCR-gamma delta cells differentiate in the thymus. Among the CD1+, TCR-gamma delta + thymocytes, no TdT positivity can be detected.     

Biochemical differences in the alphabeta T cell receptor.CD3 surface complex between CD8+ and CD4+ human mature T lymphocytes

We have reported the existence of biochemical and conformational differences in the alphabeta T cell receptor (TCR) complex between CD4(+) and CD8(+) CD3gamma-deficient (gamma(-)) mature T cells. In the present study, we have furthered our understanding and extended the observations to primary T lymphocytes from normal (gamma(+)) individuals. Surface TCR.CD3 components from CD4(+) gamma(-) T cells, other than CD3gamma, were detectable and similar in size to CD4(+) gamma(+) controls. Their native TCR.CD3 complex was also similar to CD4(+) gamma(+) controls, except for an alphabeta(deltaepsilon)(2)zeta(2) instead of an alphabetagammaepsilondeltaepsilonzeta(2) stoichiometry. In contrast, the surface TCRalpha, TCRbeta, and CD3delta chains of CD8(+) gamma(-) T cells did not possess their usual sizes. Using confocal immunofluorescence, TCRalpha was hardly detectable in CD8(+) gamma(-) T cells. Blue native gels (BN-PAGE) demonstrated the existence of a heterogeneous population of TCR.CD3 in these cells. Using primary peripheral blood T lymphocytes from normal (gamma(+)) donors, we performed a broad epitopic scan. In contrast to all other TCR.CD3-specific monoclonal antibodies, RW2-8C8 stained CD8(+) better than it did CD4(+) T cells, and the difference was dependent on glycosylation of the TCR.CD3 complex but independent of T cell activation or differentiation. RW2-8C8 staining of CD8(+) T cells was shown to be more dependent on lipid raft integrity than that of CD4(+) T cells. Finally, immunoprecipitation studies on purified primary CD4(+) and CD8(+) T cells revealed the existence of TCR glycosylation differences between the two. Collectively, these results are consistent with the existence of conformational or topological lineage-specific differences in the TCR.CD3 from CD4(+) and CD8(+) wild type T cells. The differences may be relevant for cis interactions during antigen recognition and signal transduction.     

sgp-60, a signal-transducing glycoprotein concerned with T cell activation through the T cell receptor/CD3 complex

T cell activation depends not only on the expression of a TCR, but also on that of accessory molecules that function in cell-cell adhesion and/or signal transduction. The subject of this report is the biochemical and functional characterization of what appears to be a novel murine lymphocyte cell surface antigen, provisionally termed sgp-60. Extensive, higher-order cross-linking of this glycoprotein with an anti-sgp-60 mAb and a second-step antibody reagent results in the activation of resting CD4+ T cells in the presence of a second signal. Monovalent or bivalent engagement of sgp-60 by the anti-sgp-60 antibody results in profound and direct inhibition of anti-CD3- or Con A-driven T cell activation, whereas alternative T cell activation via the phosphatidylinositol-linked proteins Thy-1 and TAP/Ly-6A is not affected. These findings raise the possibility that the sgp-60 molecule may be specifically involved in signal transduction through the TCR/CD3 complex and thus point to an important physiologic role for this protein in CD4+ T cells.     

Evidence for an association between CD8 molecules and the T cell receptor complex on cytotoxic T cells

The T cell differentiation molecule CD8 is thought to play an important role in class I major histocompatibility complex-restricted T cell activities but the precise function of this molecule is unknown. To explore this question, we have studied several CD3+, CD8+ class I alloantigen-specific cytotoxic T lymphocyte (CTL) lines and clones. The ability of these CTL to proliferate as well as to lyse specific targets was inhibited by either anti-CD3 or anti-CD8 monoclonal antibodies. Exposure of CTL to relevant but not irrelevant target cells induced the rapid (less than 1 hr) disappearance of approximately 20 to 30% of CD3 and CD8 molecules from the cell surface. The modulation of these molecules became maximal at 6 to 12 hr and recovered thereafter in parallel. Treatment of CTL with anti-CD8 prevented alloantigen-induced modulation of CD3, and treatment with anti-CD3 blocked modulation of CD8. Incubation of CTL with the combination of anti-CD3 and goat anti-mouse Ig also resulted in modulation of CD8. In contrast, the expression of other CTL surface antigens, such as CD2 (Leu-5, T11) and HLA-DR, was not reduced by any of these manipulations. These results suggest that CD8 molecules are associated with the CD3/antigen receptor complex on the surface of CTL, and may play a direct role in antigen-induced modulation and cross-linking of the T cell receptor.     

Crosslinking CD81 results in activation of TCRgammadelta T cells

CD81 is expressed on most cells and is associated with other glycoproteins, including CD4 and CD8, to form multimolecular membrane complexes. Crosslinking of CD81 on TCRalphabeta(+) T cells results in costimulatory signals that have been proposed to be mediated via CD4 or CD8. In this study, we show that CD81 is also expressed on TCRgammadelta(+)CD4(-)CD8(-) T cells. CD81 crosslinking greatly enhanced anti-CD3 activation of both TCRalphabeta(+) (CD4+ and CD8+) and TCRgammadelta(+) T cells with regard to IFN-gamma production. However, crosslinking of CD81 molecules on TCRgammadelta(+) T cells, in the absence of anti-CD3 stimulation, resulted in cytokine production and enhanced IL-2-induced proliferation, demonstrating that physical association with CD4 or CD8 is not necessary for CD81 signaling. In contrast, crosslinking of CD81 on TCRalphabeta(+) T cells, in the absence of anti-CD3 stimulation, failed to activate these T cells. These results suggest that CD81 signaling may be mediated via a different mechanism(s) in TCRgammadelta(+) versus TCRalphabeta(+) T cells.