Building a multichain receptor: synthesis, degradation, and assembly of the T-cell antigen receptor

Associations between subunit ectodomains promote T cell antigen receptor assembly and protect against degradation in the ER

The T cell antigen receptor (TCR) is an oligomeric protein complex made from at least six different integral membrane proteins (alpha beta gamma delta epsilon and zeta). The TCR is assembled in the ER of T cells, and correct assembly is required for transport to the cell surface. Single subunits and partial receptor complexes are retained in the ER where TCR alpha, beta, and CD3 delta chains are degraded selectively. The information required for the ER degradation of the TCR beta chain is confined to the membrane anchor of the protein (Wileman et al., 1990c; Bonifacino et al., 1990b). In this study we show that the rapid degradation of the TCR beta chain is inhibited when it assembles with single CD3 gamma, delta, or epsilon subunits in the ER, and have started to define the role played by transmembrane anchors, and receptor ectodomains, in the masking proteolytic targeting information. Acidic residues within the membrane spanning domains of CD3 subunits were essential for binding to the TCR beta chain. TCR beta chains and CD3 subunits therefore interact via transmembrane domains. However, when sites of binding were restricted to the membrane anchor of the TCR beta chain, stabilization by CD3 subunits was markedly reduced. Interactions between membrane spanning domains were not, therefore, sufficient for the protection of the beta chain from ER proteolysis. The presence of the C beta domain, containing the first 150 amino acids of the TCR ectodomain, greatly increased the stability of complexes formed in the ER. For assembly with CD3 epsilon, stability was further enhanced by the V beta amino acids. The results showed that the efficient neutralization of transmembrane proteolytic targeting information required associations between membrane spanning domains and the presence of receptor ectodomains. Interactions between receptor ectodomains may slow the dissociation of CD3 subunits from the beta chain and prolong the masking of transmembrane targeting information. In addition, the close proximity of TCR and CD3 ectodomains within the ER may provide steric protection from the action of proteases within the ER lumen.

Assembly of the peripheral domain of the bovine vacuolar H(+)-adenosine triphosphatase

The biosynthesis and assembly of the peripheral sector (V1) of the vacuolar proton-translocating adenosine triphosphatase (V-ATPase) was studied in a bovine kidney epithelial cell line. Monolayer cultures of cells were metabolically radiolabeled with Tran35S-label and the V-ATPase subsequently immunoprecipitated using a monoclonal antibody raised against the bovine brain-coated vesicle proton pump. The V-ATPase immunoprecipitated from the bovine kidney cell line has a subunit composition very similar to that of the bovine brain-coated vesicle proton pump and the V-ATPase prepared from other kidney tissues. Radiolabeling the cells for increasing times showed that the V1 or peripheral portion of the V-ATPase is assembled within 10-15 min; the intact V1V0 complex is also detectable within 10-15 min. Fractionation of the cells into cytosolic and membrane components prior to immunoprecipitation revealed that there is a significant pool of V1 in the cytosol; a similar complex is also found in bovine brain cytosol. Pulse-chase studies suggest that this cytosolic pool is not an obligate precursor for membrane-bound V1V0 and does not exchange with the membrane V1 population at later times. No qualitative differences in assembly were observed when pulse-chase studies were performed at 15 degrees C or in the presence of brefeldin A. This suggests that assembly of V1V0 is probably completed in the endoplasmic reticulum prior to distribution of the enzyme throughout the cell, with a cytosolic pool of V1 of unknown function existing in parallel with the fully assembled complex.

Identification of a nonsense mutation at amino acid 584-arginine of platelet glycoprotein IIb in patients with type I Glanzmann thrombasthenia

Using Southern blot, the restriction digests of genomic DNAs in 11 patients with Glanzmann thrombasthenia from 10 unrelated kindreds were probed with a full-length GPIIb cDNA. An additional 2.3 kb Taq I fragment and two 1.65 kb and 0.65 kb fragments with reduced band intensity were found in the genes of two affected siblings from a family originating from the city of Huang Yan in the Zhejiang province. The Taq I digest of the abnormal gene was further probed with three portions of GPIIb cDNA, revealing that the heterozygous mutation was present in the region around exons 15-17 of the GPIIb gene. Two primers for polymerase chain reaction (PCR) were then designed, and a 394 bp PCR product was generated and sequenced, indicating that a stop codon (TGA) was substituted for an Arg codon (CGA) at amino acid position 584 of GPIIb, and resulted in a premature termination of translation and production of a shortened protein. The Western blot analysis showed that GPIIIa at the platelet surface was apparently deficient, it may be ascribed to the rapid turn-over of GPIIIa uncomplexed with the truncated GPIIb. The abnormal 2.3 kb Taq I fragment was used as a specific genetic marker to detect the carrier status of the patient family. The abnormal allele was proved to be derived from the mother, the two affected siblings are double heterozygotes, and one clinically unaffected daughter has also inherited this defective allele, while the father carries another recessive abnormal allele unidentified.

Do anergic T cells induce suppressor T lymphocytes through idiotypic interactions?

Suppression by T cells and T cell anergy have been implied, at different periods of immunological research, as the main agents of peripheral down regulation of the immune response. This article discusses the possibility that anergic T cells, with the participation of appropriate co-stimulatory molecules on their membranes, stimulate CD8 cells with an alpha/beta TCR specific for peptides of the TCR of the anergic cell itself processed and presented by class I MHC. The non-anergic (orthoergic) members of the same clone, if activated, process and present their TCR in the same way, but, lacking the co-stimulatory molecule, are unable to stimulate the anti-idiotype CD8 cells. On the other hand the orthoergic, but not the anergic, cells can be induced into death (possibly by apoptosis) by the specific CD8 lymphocytes or, alternatively, can be pushed into the anergic pool by the same CD8 suppressors, thus contributing to the generation of a TCR-restricted circuit in which suppression is dominant. This simple immunosuppressive circuit can adequately explain some recent experiments on the course of experimental allergic encephalomyelitis. It is to be stressed that many elements of the proposal are hypothetical. They are, however, open to experimental study.

Requirement for CD8+ cells in T cell receptor peptide-induced clonal unresponsiveness

T cell receptor (TCR) vaccination in rats prevents the development of experimental allergic encephalomyelitis (EAE), an animal model of multiple sclerosis. The mechanism of this potential immunotherapy was examined by vaccinating mice with an immunogenic peptide fragment of the variable region of the TCR V beta 8.2 gene. Another immunogen that usually induces an immune response mediated by V beta 8.2+ T cells was subsequently inhibited because specific clonal unresponsiveness (anergy) had been induced. Depletion of CD8+ cells before TCR peptide vaccination blocked such inhibition. Thus, the clonal anergy was dependent on CD8+ T cells, and such immunoregulatory T cells may participate in the normal course of EAE.

The respiratory burst oxidase and the molecular genetics of chronic granulomatous disease

The phagocyte respiratory burst oxidase plays a central role in the inflammatory response. This membrane-bound enzyme complex is comprised of both integral membrane and cytosolic proteins and catalyzes the formation of large quantities of superoxide in response to inflammatory stimuli. While superoxide and its oxidant derivatives normally serve a microbicidal function, excessive or inappropriate release of these products contribute to inflammatory tissue injury. Chronic granulomatous disease (CGD) is a group of inherited disorders characterized by an absent neutrophil respiratory burst, which leads to recurrent and often life-threatening infections in affected patients. The analysis of the specific cellular defects in CGD has been instrumental in the identification and characterization of individual oxidase components. Four distinct genetic subgroups are presently recognized, each involving a different protein essential for respiratory burst oxidase function. This article summarizes recent advances in the characterization of the protein components and cellular biochemistry of the respiratory burst oxidase and reviews the classification and molecular genetics of CGD. The application of these findings to new approaches to the diagnosis and treatment of CGD are also reviewed.

Alterations in signal transduction molecules in T lymphocytes from tumor-bearing mice

Impaired immune responses occur frequently in cancer patients or in tumor-bearing mice, but the mechanisms of the tumor-induced immune defects remain poorly understood. In an in vivo murine colon carcinoma model (MCA-38), animals bearing a tumor longer than 26 days develop CD8+ T cells with impaired cytotoxic function, decreased expression of the tumor necrosis factor-alpha and granzyme B genes, and decreased ability to mediate an antitumor response in vivo. T lymphocytes from tumor-bearing mice expressed T cell antigen receptors that contained low amounts of CD3 gamma and completely lacked CD3 zeta, which was replaced by the Fc epsilon gamma-chain. Expression of the tyrosine kinases p56lck and p59fyn was also reduced. These changes could be the basis of immune defects in tumor-bearing hosts.

Instability of assembled T-cell receptor complex that is associated with rapid degradation of zeta chains in immature CD4+CD8+ thymocytes

The intracellular fate of newly synthesized T-cell receptor (TCR) chains was compared in CD4+CD8+ (double positive; DP) thymocytes and in CD4+CD8- or CD4-CD8+ (single positive; SP) thymocytes. Purified DP and SP thymocytes from normal adult mice were analyzed by pulse-chase metabolic labeling and immunoprecipitation with specific anti-TCR antibodies. Biosynthesis of invariant chains (CD3 gamma, -delta, -epsilon, and zeta) was comparable between DP and SP thymocytes, whereas DP thymocytes synthesized TCR alpha and TCR beta chains at lower and higher levels than SP thymocytes, respectively. These newly synthesized TCR chains were degraded at different rates in SP thymocytes based on their sensitivities for degradation as previously reported: TCR alpha, TCR beta, CD3 gamma, and CD3 delta chains were rapidly degraded and CD3 epsilon and zeta chains were stable. Although the degradation rates of clonotypic and invariant CD3 chains were similar in DP and SP thymocytes, the zeta subunit was rapidly degraded in DP thymocytes (t1/2, approximately 1.5 hr). Degradation of zeta was inhibited by NH4Cl, implicating lysosomes as the site of degradation. Comparison of TCR subunit assembly in DP and SP thymocytes demonstrated that, despite the same relative rate of formation of TCR complexes in a pulse period (30 min), complete complexes were unstable and degraded during the subsequent 6 hr of chase in DP thymocytes. This contrasted with the stability and a progressive increase in the levels of completely assembled complexes in SP thymocytes. Thus, these results demonstrate that a unique posttranslational regulation operates in the formation of TCR complexes in DP thymocytes and that lack of stability of complete TCR complexes is a crucial mechanism that may account for the limited surface TCR expression on this thymocyte subset.

CD3-gamma, -delta, -epsilon, -zeta, T-cell receptor-alpha and -beta transcripts are independently regulated during thymocyte ontogeny and T-cell activation

CD3 proteins transduce signals delivered from the T-cell receptor (TcR) for antigen. The genes that encode the individual CD3 subunits are asynchronously regulated in tumour cell lines in vitro. In this report, we examined the expression of individual CD3 and TcR genes during normal murine thymocyte ontogeny in vivo. We show that CD3-gamma, -delta, -epsilon, and zeta transcripts are all expressed on Day 14 post-coitum (p.c.), along with IL-2R alpha and Thy-1 mRNA, and prior to the expression of functional TcR-alpha, -beta, CD4 and CD8 transcripts. Individual CD3 subunits display unique patterns of increased gene expression as ontogeny proceeds. Unique regulation of these T-cell transcripts is also observed in splenic cells activated with the T-cell mitogen concanavalin A (Con A). CD3-delta, -zeta, TcR-alpha and -beta mRNA expression increases, whilst CD3-gamma and -epsilon mRNA levels decrease after mitogenic activation. The potential implications of this regulation on the composition and expression of the TcR/CD3 complex during T-cell ontogeny and activation is discussed.

Membrane protein sorting in the yeast secretory pathway: evidence that the vacuole may be the default compartment

The targeting signals of two yeast integral membrane dipeptidyl aminopeptidases (DPAPs), DPAP B and DPAP A, which reside in the vacuole and the Golgi apparatus, respectively, were analyzed. No single domain of DPAP B is required for delivery to the vacuolar membrane, because removal or replacement of either the cytoplasmic, transmembrane, or lumenal domain did not affect the protein's transport to the vacuole. DPAP A was localized by indirect immunofluorescence to non-vacuolar, punctate structures characteristic of the yeast Golgi apparatus. The 118-amino acid cytoplasmic domain of DPAP A is sufficient for retention of the protein in these structures, since replacement of the cytoplasmic domain of DPAP B with that of DPAP A resulted in an immunolocalization pattern indistinguishable from that of wild type DPAP A. Overproduction of DPAP A resulted in its mislocalization to the vacuole, because cells expressing high levels of DPAP A exhibited vacuolar as well as Golgi staining. Deletion of 22 residues of the DPAP A cytoplasmic domain resulted in mislocalization of the mutant protein to the vacuole. Thus, the cytoplasmic domain of DPAP A is both necessary and sufficient for Golgi retention, and removal of the retention signal, or saturation of the retention apparatus by overproducing DPAP A, resulted in transport to the vacuole. Like wild type DPAP B, the delivery of mutant membrane proteins to the vacuole was unaffected in the secretory vesicle-blocked sec1 mutant; thus, transport to the vacuole was not via the plasma membrane followed by endocytosis. These data are consistent with a model in which membrane proteins are delivered to the vacuole along a default pathway.

Baculovirus mediated expression of human phagocytic cell oxidase cytochrome b558 in sf9 insect cells

Chronic granulomatous disease (CGD) results from deficient production of components of the phagocyte NADPH oxidase. Most commonly affected is cytochrome b558, a heterodimer composed of a 22-kDa protein (p22phox) noncovalently bound to a 91-kDa transmembrane glycoprotein (gp91phox). CGD phagocytes lack both p22phox and gp91phox peptides when either gene is affected, suggesting that both peptides must be produced for individual subunit stability. Both genes have been cloned, but eukaryotic expression of recombinant gp91phox has not been reported. To investigate the stability and interaction of cytochrome b558 subunits, we introduced p22phox and gp91phox cDNA into recombinant baculoviruses. Recombinant gp91phox (rgp91phox) and p22phox (rp22phox) were detected individually and together in the same cells by in situ immunofluorescence and by SDS-PAGE immunoblotting of membranes from sf9 cells infected with baculovirus constructs. Formation of rp22phox/rgp91phox complexes was demonstrated by coprecipitation using subunit-specific antibodies. This study demonstrates for the first time that cDNA encoding either subunit is capable of initiating production of stable recombinant cytochrome b558 subunits in eukaryotic cells.

Endoplasmic reticulum resident protein of 90 kilodaltons associates with the T- and B-cell antigen receptors and major histocompatibility complex antigens during their assembly

In the endoplasmic reticulum (ER), newly synthesized subunits of the T-cell antigen receptor (TCR), membrane-bound immunoglobulin (mIg), and major histocompatibility complex (MHC) class I antigens must fold correctly and assemble completely into multimeric protein complexes prior to transport to the cell surface. Although folding and assembly may occur spontaneously, the concept that molecular chaperones facilitate these events is emerging. Here, an intracellular protein of 90-kDa apparent molecular mass, denoted IP90, was shown to be an ER resident protein that associated with partial complexes of the TCR, mIg, and MHC class I proteins but was absent from fully assembled complexes. We speculate that IP90 might participate in folding and assembly processes of these and other multisubunit protein complexes during their transit through the ER.

Immunoregulatory activity of the T-cell receptor alpha chain demonstrated by retroviral gene transfer

We have previously described an antigen-specific I-Ad-restricted T-cell hybridoma, A1.1, that constitutively releases an antigen-specific immunoregulatory activity into supernatants. Using retrovirally mediated gene transfer, we have found that transfer of the T-cell receptor alpha chain (TCR alpha) gene from A1.1 to a number of other T-cell hybridomas effectively transferred the ability to produce the activity. Gene transfer of the TCR beta chain (TCR beta), however, did not transfer this ability. The regulatory activity from cells expressing the A1.1 TCR alpha bound to and was eluted from an anti-TCR alpha monoclonal antibody and displayed fine antigenic specificity identical to that of supernatants from A1.1. The possibility that this activity represents a secreted form of the TCR alpha (as opposed to shed cell-surface TCR) was examined in BW1100 cells, lacking TCR alpha and TCR beta, which produced the antigen-specific activity after gene transfer of the A1.1 TCR alpha gene. The expression of the immunoregulatory activity in supernatants correlated with a direct antigen-binding activity as detected by ELISA, thus raising the possibility that antigen binding is relevant to the mechanism of action of the soluble TCR alpha. We discuss these observations and our earlier studies suggesting an immunoregulatory role for soluble TCR alpha.

Identification of a murine monoclonal antibody specific for an allotypic determinant on mouse CD3

A murine monoclonal antibody (mAb; 7D6) that was mitogenic for T cells was derived from 129/Sv animals immunized with a T helper clone from C57BL/6 origin. Fluoresceinated 7D6 labeled T cells from most common mouse strains but not from 129/Sv and LP/J animals, and this labeling was inhibited by the anti-CD3 epsilon mAb 145-2C11. The mitogenicity of 7D6 for T cells had a similar strain specificity. The antibody immunoprecipitated the T cell receptor (TcR) complex from a T cell hybridoma. After dissociation of this immunoprecipitate with detergents, the CD3 gamma and epsilon chains were retained by the 7D6 antibody. Immunoprecipitation data were also obtained with COS cells transfected with the CD3 gamma, delta or epsilon chains alone, in pairs or together. They confirmed that 7D6 bound the CD3 gamma epsilon pair, suggesting that the antibody recognizes a conformational epitope formed by gamma epsilon pairing, whereas 145-2C11 bound both gamma epsilon and delta epsilon pairs. These results, therefore, add to current information about TcR structure and subunit stoichiometry. We have demonstrated that the 7D6 mAb specifically binds to a CD3 dimer comprised of gamma and epsilon chains. We thus provide additional evidence that indicates that two CD3 epsilon chains are found within the receptor, one linked to CD3 gamma and the other to CD3 delta.

Regions of the T cell receptor alpha and beta chains that are responsible for interactions with CD3

The T cell antigen receptor consists of the Ti alpha/beta heterodimer which recognizes antigen, and the associated CD3 chains, thought to be involved in signal transduction. To understand the nature of the interaction between Ti and CD3, chimeric molecules which included the COOH-terminal segments of Ti alpha or beta linked to the extracellular segment of CD8, were transfected into a mutant T cell deficient in Ti beta chain expression and cell surface CD3. Both chimeric chains were required to express the chimeric Ti and to restore CD3 surface expression. CD8/Ti and CD3 cointernalized and coimmunoprecipitated. Stimulation of the chimeric receptor induced transmembrane signaling events and cell activation. These results demonstrate that the Ti alpha and beta COOH termini containing the transmembrane domains are sufficient for structural and functional coupling of Ti to CD3.

Participation of a novel 88-kD protein in the biogenesis of murine class I histocompatibility molecules

Chemical cross-linking and gel permeation chromatography were used to examine early events in the biogenesis of class I histocompatibility molecules. We show that newly synthesized class I heavy chains associate rapidly and quantitatively with an 88-kD protein in three murine tumor cell lines. This protein (p88) does not appear to possess Asn-linked glycans and it is not the abundant ER protein, GRP94. The class I-p88 complex exists transiently (t1/2 = 20-45 min depending on the specific class I heavy chain) and several lines of evidence suggest that p88 dissociates from the complex while still in the ER. Dissociation is not triggered upon binding of beta 2-microglobulin to the heavy chain (t1/2 = 2-5 min). However, the rate of dissociation does correlate with the characteristic rate of ER to Golgi transport for the particular class I molecule studied. Consequently, dissociation of p88 may be rate limiting for ER to Golgi transport. Class I molecules bind antigenic peptides, apparently in the ER, for subsequent presentation to cytotoxic T lymphocytes at the cell surface. p88 could promote peptide binding or it may retain class I molecules in the ER during formation of the ternary complex of heavy chain, beta 2-microglobulin, and peptide.

Genetic reconstitution of the T cell receptor (TcR) alpha/beta heterodimer restores the association of CD3 zeta 2 with the TcR/CD3 complex

The cell surface expression of the T cell receptor (TcR)/CD3 complex and, consequently, the functional competence of the cell is partly dependent on CD3 zeta. In its absence, a pentameric complex (TcR alpha/beta/CD3 gamma delta epsilon) is formed which is inefficiently transported to the cell surface. Reconstitution of CD3 zeta by transfection, in turn, restores the cell surface expression and function of the complex. Through the use of transfection experiments, we here provide direct evidence that the association of CD3 zeta 2 with the TcR/CD3 complex is dependent on the presence of both the TcR alpha and beta polypeptide chains. Despite wild-type levels of the CD3 zeta protein in a TcR alpha-negative mutant human T cell line, a complex was formed intracellularly which lacked CD3 zeta 2 and consisted of beta gamma delta epsilon and beta 2 gamma delta epsilon. Upon transfection of the mutant with a TcR alpha cDNA, a TcR/CD3 complex which contained CD3 zeta 2 was observed intracellularly. In contrast to the partial subcomplex on the cell surface of the untransfected cell line, the TcR/CD3 complex on the transfectant was functional as demonstrated by its ability to mobilize intracellular calcium after stimulation with a mitogenic CD3 epsilon-specific monoclonal antibody. Transient transfection studies performed in COS cell fibroblasts indicated that CD3 zeta 2 was not interacting with the TcR alpha protein alone, implying that a conformation provided by either the TcR alpha/beta heterodimer or the TcR alpha/beta/CD3 gamma delta epsilon complex was necessary for the association of CD3 zeta 2. Transfection studies performed in a TcR alpha/beta-negative murine T-T hybridoma confirmed the requirement of both the TcR alpha and beta proteins in CD3 zeta 2 binding. We conclude that the TcR alpha and beta chains harbor polypeptide sequences essential for the association of CD3 zeta 2 with the TcR/CD3 complex.

Formation and intracellular transport of a heterodimeric viral spike protein complex

We have analyzed the heterodimerization and intracellular transport from the ER to the Golgi complex (GC) of two membrane glycoproteins of a bunyavirus (Uukuniemi virus) that matures by a budding process in the GC. The glycoproteins G1 and G2, which form the viral spikes, are cotranslationally cleaved in the ER from a 110,000-D precursor. Newly synthesized G1 was transported to the GC and incorporated into virus particles about 30-45 min faster than newly synthesized G2. Analysis of the kinetics of intrachain disulfide bond formation showed that G1 acquired its mature form within 10 min, while completion of disulfide bond formation of G2 required a considerably longer time (up to 60 min). During the maturation process, G2 was transiently associated with the IgG heavy chain binding protein for a longer time than G1. Protein disulfide isomerase also coprecipitated with antibodies against G1 and G2. In virus particles, G1 and G2 were present exclusively as heterodimers. Immunoprecipitation with monoclonal antibodies showed that heterodimerization occurred rapidly, probably in the ER, between newly made G1 and mature, dimerization competent G2. Taken together, our results show that these two viral glycoproteins have different maturation kinetics in the ER. We conclude that the apparent different kinetics of ER to GC transport of G1 and G2 is due to the different rates by which these proteins fold and become competent to enter into heterodimeric complexes prior to exit from the ER.

Structure of the T cell antigen receptor (TCR): two CD3 epsilon subunits in a functional TCR/CD3 complex

Transgenic mice carrying and expressing the human CD3 epsilon gene incorporate the corresponding protein product into T cell receptor (TCR)/CD3 complexes on thymocyte and T cell surfaces. The chimeric antigen receptors allow normal T cell development and selection of repertoires in vivo and are able to transduce activation signals in vitro. We have exploited the ability to distinguish mouse (m) and human (h)CD3 epsilon chains to analyze the stoichiometry of CD3 epsilon in transgenic mouse TCRs. Immunoprecipitation and fluorescence resonance energy transfer experiments demonstrate that such TCRs can contain both h- and mCD3 epsilon chains, implying that more than one CD3 epsilon subunit occurs per TCR. Antigen comodulation studies are consistent with a stochastic use of h- or mCD3 epsilon during receptor assembly, and further suggest a structure for the TCR/CD3 complex with two CD3 epsilon chains. The determination of CD3 epsilon subunit stoichiometry, together with existing biochemical data, allows the generation of a minimal model for the structure of the TCR and illustrates the potential value of the transgenic approach to the analysis of complex receptors.

Human neutrophil cytochrome b light chain (p22-phox). Gene structure, chromosomal location, and mutations in cytochrome-negative autosomal recessive chronic granulomatous disease

A membrane-bound cytochrome b, a heterodimer formed by a 91-kD glycoprotein (heavy chain) and a 22-kD polypeptide (light chain), is an essential component of the phagocyte NADPH-oxidase responsible for superoxide generation. Cytochrome b is absent in two subgroups of chronic granulomatous disease (CGD), an inherited disorder characterized by the lack of oxidase activity. Mutations in the cytochrome heavy chain gene, encoded by the CYBB locus in Xp21.1, result in the X-linked form of CGD. A rare subgroup of autosomal recessive CGD also lacks cytochrome b (A- CGD), but the genetic defect has not previously been identified. In order to search for possible mutations in the cytochrome light chain locus, CYBA, the structure of this gene was characterized. The CYBA locus was localized to 16q24, and the approximately 600-bp open reading frame determined to be encoded by six exons that span approximately 8.5 kb. Three unrelated patients with A- CGD were studied for evidence of mutations in the light chain gene. One patient, whose parents were first cousins, was homozygous for a large deletion that removed all but the extreme 5' coding sequence of the gene. The other two patients had a grossly normal light chain transcript on Northern blot of mononuclear cell RNA. The light chain transcript was amplified by the polymerase chain reaction and sequenced. One patient was a compound heterozygote for two alleles containing point mutations in the open reading frame that predict a frame shift and a nonconservative amino acid replacement, respectively. The second patient, whose parents were second cousins, was homozygous for a different single-base substitution resulting in another nonconservative amino acid change. These results indicate that A- CGD can results from defects in the gene encoding the 22-kD light chain of the phagocyte cytochrome b.

A specific defect in CD3 gamma-chain gene transcription results in loss of T-cell receptor/CD3 expression late after human immunodeficiency virus infection of a CD4+ T-cell line

Sequential effects on cellular protein expression following human immunodeficiency virus (type 1) infection of a CD4+ T-cell line in vitro were investigated. Events in the human interleukin 2-dependent helper T-cell line WE17/10 are similar in several respects to the clinical progression in acquired immunodeficiency syndrome. WE17/10 cell infection is characterized by an extended period during which viral replication occurs without accompanying cytotoxicity and with a maximum 30% decrease in surface CD4. Cellular protein expression generally remains unaffected during this first phase of infection. However, after 2-3 months, a severe defect in the expression of the T-cell receptor/CD3 complex both on the cell surface and inside the cell becomes apparent. Other cell membrane markers, such as CD2 and CD25, remain constant throughout the course of infection; after its initial decrease, CD4 remains at 70% of control values. Lack of surface expression of the TCR/CD3 complex is correlated with a specific defect in transcription of the CD3 gamma-chain gene.

Invariant chain trimers are sequestered in the rough endoplasmic reticulum in the absence of association with HLA class II antigens

HLA class II antigens are heterodimeric cell surface glycoproteins that interact with antigenic peptides to form complexes recognizable by CD4-positive T cells. During their biosynthesis, class II antigens are retained in a post-Golgi compartment in association with the invariant chain, which dissociates before class II cell surface expression. To address whether the invariant chain mediates this post-Golgi retention, its transport and assembly were examined in cells that do not express HLA class II antigens. Pulse-chase analysis and endoglycosidase digestions showed that very little invariant chain proceeded as far as the trans-Golgi in class II-negative cell lines. Immunofluorescence studies suggested that in these cells the invariant chain is sequestered in the RER. Gel filtration and cross-linking data showed that RER-localized invariant chain is present as trimers or aggregated trimers. Multimerization is mediated by lumenal interactions; a proteolytic fragment of the invariant chain corresponding to the lumenal domain remained trimeric as determined by cross-linking analysis. Similar transport and structural characteristics were observed for a pool of excess invariant chain in class II-positive cells, suggesting that an excess of invariant chain in the ER may be important for class II antigen function. These results have important implications for the transport of cellular proteins in general and for the role of the invariant chain in class II antigen biosynthesis.

Structural mutations of the T cell receptor zeta chain and its role in T cell activation

T cell hybridomas that express zeta zeta, but not zeta eta, dimers in their T cell receptors (TCRs) produce interleukin-2 (IL-2) and undergo an inhibition of spontaneous growth when activated by antigen, antibodies to the receptor, or antibodies to Thy-1. Hybridomas without zeta and eta were reconstituted with mutated zeta chains. Cytoplasmic truncations of up to 40% of the zeta molecule reconstituted normal surface assembly of TCRs, but antigen-induced IL-2 secretion and growth inhibition were lost. In contrast, cross-linking antibodies to the TCR activated these cells. A point mutation conferred the same signaling phenotype as did the truncations and caused defective antigen-induced tyrosine kinase activation. Thus zeta allows the binding of antigen/major histocompatibility complex (MHC) to alpha beta to effect TCR signaling.

The gamma and epsilon subunits of the CD3 complex inhibit pre-Golgi degradation of newly synthesized T cell antigen receptors

The T cell receptor for antigen (TCR) is composed of six different transmembrane proteins. T cells carefully control the intracellular transport of the receptor and allow only complete receptors to reach the plasma membrane. In an attempt to understand how T cells regulate this process, we used c-DNA transfection and subunit-specific antibodies to follow the intracellular transport of five subunits (alpha beta gamma delta epsilon) of the receptor. In particular, we assessed the intracellular stability of each chain. Our results showed that the chains were markedly different in their susceptibility to intracellular degradation. TCR alpha and beta and CD3 delta were degraded rapidly, whereas CD3 gamma and epsilon were stable. An analysis of the N-linked oligosaccharides of the glycoprotein subunits suggested that the chains were unable to reach the medial Golgi during the metabolic chase. This was supported by immunofluorescence micrographs that showed both the stable CD3 gamma and unstable CD3 delta chain localized in the endoplasmic reticulum. To study the effects of subunit associations on intracellular transport we used cotransfection to reconstitute precise combinations of subunits. Associations between stable and unstable subunits expressed in the same cell led to the formation of stable complexes. These complexes were retained in or close to the endoplasmic reticulum. The results suggested that the intracellular transport of the T cell receptor could be regulated by two mechanisms. The TCR alpha and beta and CD3 delta subunits were degraded rapidly and as a consequence failed to reach the plasma membrane. CD3 gamma or epsilon were stable but were retained inside the cell. The results also demonstrated that there was an interplay between the two pathways such that the CD3 gamma and epsilon subunits were able to protect labile chains from rapid intracellular degradation. In this way, they could seed subunit assembly in or close to the endoplasmic reticulum and allow a stable receptor to form before its transport to the plasma membrane.

Novel post-translational regulation of TCR expression in CD4+CD8+ thymocytes influenced by CD4

Expression of the multicomponent T-cell antigen receptor (TCR) complex on the surface of thymocytes is developmentally controlled. Most immature CD4-CD8- 'double negative' and CD4+CD8+ 'double positive' thymocytes express either no or few TCR on their surface, and maturation to CD4+CD8- or CD4-CD8+ 'single positive' thymocytes is accompanied by a dramatic increase in the number of surface TCR complexes. Although the initial appearance of TCR during differentiation results from rearrangement and initiation of transcription of TCR genes in the thymus, the mechanisms regulating the quantitative changes in TCR expression during intrathymic differentiation are unknown. Surface TCR levels in T-hybridoma cells can be quantitatively regulated by a series of post-translational processes, including sorting to alternative intracellular compartments and degradation, which ensure that only fully and correctly assembled receptor complexes are efficiently transported to the cell surface. Quantitative increases in TCR expression on the surface of CD4+CD8+ thymocytes occur in vivo in response to anti-CD4 antibody treatment. Here we present evidence that immature CD4+CD8+ thymocytes normally retain and degrade in the endoplasmic reticulum greater than 90% of some endogenously synthesized TCR chains, and that the increased surface TCR expression on immature CD4+CD8+ thymocytes induced by anti-CD4 is due to an increase in the escape of newly synthesized receptor chains from the endoplasmic reticulum, and is not due to increases in RNA levels, translation, or assembly. Post-translational mechanisms therefore control the levels of TCR complexes on CD4+CD8+ thymocytes, and these mechanisms can be modulated by signalling through CD4 surface molecules.

The implications of subunit interactions for the structure of the T cell receptor-CD3 complex

Cell surface-expressed receptors are often multichain complexes. One of these, the T cell receptor (TcR) alpha/beta-CD3 complex, is known to contain at least seven chains: the alpha and beta TcR chains plus the gamma, delta, epsilon and two zeta chains from the CD3 complex (alpha beta gamma delta epsilon zeta 2). To gain insight into the structure of the complex we have used anti-peptide antisera specific for the individual subunits of the complex, and nonionic and ionic detergents to determine subunit interactions within the complex. Four closely associated pairs of chains could be identified: alpha beta, zeta 2, gamma epsilon and delta epsilon. Interactions between the TcR alpha beta and either gamma epsilon or delta epsilon could be observed in the apparent absence of other CD3 chains. Furthermore, a hierarchy in the strength of the association between the TcR and the individual CD3 chains could be distinguished: TcR epsilon greater than TcR delta greater than TcR gamma. The zeta 2 dimer could only be detected in "intact" TcR-CD3 complexes shedding no light on possible interactions with either the TcR or CD3-gamma, delta and epsilon chains. Finally, cross-linking experiments suggest a close spatial relationship between the TcR alpha beta and both the CD3-gamma and CD3-epsilon chains. The results demonstrate that the methods used give valuable information on subunit interactions in a cell surface-expressed receptor complex and suggest a TcR-CD3 complex in which two epsilon chains are present, one linked to gamma and the other to delta. The data further indicate that gamma epsilon and delta epsilon complexes interact directly with the TcR chains. Based on the observations a model for the structure of the TcR-CD3 is presented and discussed.

Intracellular degradation of unassembled asialoglycoprotein receptor subunits: a pre-Golgi, nonlysosomal endoproteolytic cleavage

The human asialoglycoprotein receptor is a heterooligomer of the two homologous subunits H1 and H2. As occurs for other oligomeric receptors, not all of the newly made subunits are assembled in the RER into oligomers and some of each chain is degraded. We studied the degradation of the unassembled H2 subunit in fibroblasts that only express H2 (45,000 mol wt) and degrade all of it. After a 30 min lag, H2 is degraded with a half-life of 30 min. We identified a 35-kD intermediate in H2 degradation; it is the COOH-terminal, exoplasmic domain of H2. After a 90-min chase, all remaining intact H2 and the 35-kD fragment were endoglycosidase H sensitive, suggesting that the cleavage generating the 35-kD intermediate occurs without translocation to the medial Golgi compartment. Treatment of cells with leupeptin, chloroquine, or NH4Cl did not affect H2 degradation. Monensin slowed but did not block degradation. Incubation at 18-20 degrees C slowed the degradation dramatically and caused an increase in intracellular H2, suggesting that a membrane trafficking event occurs before H2 is degraded. Immunofluorescence microscopy of cells with or without an 18 degrees C preincubation showed a colocalization of H2 with the ER and not with the Golgi complex. We conclude that H2 is not degraded in lysosomes and never reaches the medial Golgi compartment in an intact form, but rather degradation is initiated in a pre-Golgi compartment, possibly part of the ER. The 35-kD fragment of H2 may define an initial proteolytic cleavage in the ER.

Surface expression of CD3 in the absence of T cell receptor (TcR): evidence for sorting of partial TcR/CD3 complexes in a post-endoplasmic reticulum compartment

The T cell receptor (TcR) for antigen, on the majority of T cells, is a disulfide-linked heterodimer composed of the alpha and beta chains, noncovalently associated with the CD3 complex of polypeptides (gamma, delta, epsilon and zeta). In this report, two murine thymoma cell lines are described which synthesized incomplete TcR/CD3 complexes and expressed low levels of CD3 on their surface in the absence of the TcR chains. The partial TcR/CD3 complexes were composed primarily of the inherently metabolically stable CD3 gamma and epsilon subunits. These results were in contrast to previous studies, which suggested that synthesis of all of the component chains of the TcR/CD3 complex is required for the successful transport of any of the chains to the cell surface. The efficiency of transport of the partial TcR/CD3 complexes from the endoplasmic reticulum (ER) to medial Golgi in the two thymomas was similar to complete complexes. However, the transport of the incomplete receptors was impaired at some point between the medial Golgi and the plasma membrane. Taken together with previous studies, these results suggested that T cells have mechanisms to retain partial TcR/CD3 complexes intracellularly both in the ER and in an undefined post-ER compartment. However, the transport of low levels of partial TcR/CD3 complexes to the cell surface in some T cell lines implied that the retention mechanisms may not always be completely efficient. Cross-linking of the surface, partial TcR/CD3 complexes with anti-CD3 epsilon antibodies did not stimulate interleukin 2 (IL 2) production. It is possible, however, that the partial TcR/CD3 complexes have some function which is unrelated to the stimulation of IL 2 production.