Importance of the T cell receptor alpha-chain transmembrane distal region for assembly with cognate subunits.

Antigen recognition by alphabeta T lymphocytes is mediated via the multisubunit TCR complex consisting of invariant CD3gamma,delta,epsilon and zeta chains associated with clonotypic TCRalpha and beta molecules. Charged amino acids located centrally within the TCRalpha transmembrane region are necessary and sufficient for assembly with the CD3deltaepsilon heterodimer. Previously, we have shown that deletion of 6-12 amino acids from the carboxy terminus of the TCRalpha-chain dramatically abrogates surface TCR expression, suggesting that the distal portion of the TCRalpha transmembrane region contains information that regulates the assembly and/or intracellular transport of TCR complexes. We have examined in more detail the molecular basis for reduced TCR expression in T cells bearing truncated TCRalpha chains. We found that in contrast to wild-type (wt), variant TCRalpha proteins missing the last nine C-terminal amino acids did not associate with core CD3gamma,delta,epsilon chains and were not assembled into disulphide-linked alphabeta heterodimers. The stability of newly synthesised wt and variant TCRalpha molecules was similar, showing that the abrogated surface TCR expression was not a consequence of impaired protein survival. Nevertheless, truncated TCRalpha chains still assembled with the chaperon protein calnexin in the endoplasmic reticulum, indicating that the distal portion of the TCRalpha transmembrane region is not essential for calnexin interaction. These data document a role for the distal portion of the TCRalpha transmembrane region in the assembly of TCR complexes and provide a molecular basis for reduced TCR expression in cells bearing truncated TCRalpha chains.

Monoclonal antibody DS6 detects a tumor-associated sialoglycotope expressed on human serous ovarian carcinomas.

A newly developed murine monoclonal antibody, DS6, immunohistochemically reacts with an antigen, CA6, that is expressed by human serous ovarian carcinomas but not by normal ovarian surface epithelium or mesothelium. CA6 has a limited distribution in normal adult tissues and is most characteristically detected in fallopian tube epithelium, inner urothelium and type 2 pneumocytes. Pre-treatment of tissue sections with either periodic acid or neuraminidase from Vibrio cholerae abolishes immunoreactivity with DS6, indicating that CA6 is a neuraminidase-sensitive and periodic acid-sensitive sialic acid glycoconjugate ("sialoglycotope"). SDS-PAGE of OVCAR5 cell lysates has revealed that the CA6 epitope is expressed on an 80 kDa non-disulfide-linked glycoprotein containing N-linked oligosaccharides. Two-dimensional non-equilibrium pH gradient gel electrophoresis indicates an isoelectric point of approximately 6.2 to 6.5. Comparison of the immunohistochemical distribution of CA6 in human serous ovarian adenocarcinomas has revealed similarities to that of CA125; however, distinct differences and some complementarity of antigen expression were revealed by double-label, 2-color immunohistochemical studies. The DS6-detected CA6 antigen appears to be distinct from other well-characterized tumor-associated antigens, including MUC1, CA125 and the histo-blood group-related antigens sLea, sLex and sTn.

T cell receptor assembly and expression in the absence of calnexin.

Most subunits of the alphabeta deltaepsilon gammaepsilon zetazeta T cell antigen receptor (TCR) complex associate with the molecular chaperone calnexin shortly after their synthesis in the endoplasmic reticulum, including clonotypic TCRalpha,beta molecules and invariant CD3gamma,delta,epsilon chains. While calnexin interaction is suggested to be important for the stability of newly synthesized TCRalpha subunits, the role of calnexin in the survival and assembly of remaining TCR components is unknown. Here we evaluated the expression of TCR proteins in CEM T cells and the calnexin-deficient CEM variant CEM.NK(R). We found that CEM and CEM.NK(R) cells constitutively synthesized all TCR subunits except for TCRalpha and that CD3gamma,delta,epsilon components and CD3-beta complexes were effectively assembled together in both cell types. The stability and folding of core CD3epsilon chains were similar in CEM and CEM.NK(R) cells. Interestingly, TCRalpha synthesis was differentially induced by phorbol myristate acetate treatment in CEM and CEM.NK(R) cells and TCRalpha proteins synthesized in CEM.NK(R) cells showed reduced survival compared to those made in CEM cells. Importantly, these data show that TCR complexes were inducibly expressed on CEM.NK(R) cells in the absence of calnexin synthesis. These results demonstrate that TCR complexes can be expressed in the absence of calnexin and suggest that the role of calnexin in the quality control of TCR assembly is primarily restricted to the stabilization of newly synthesized TCRalpha proteins.

A useful radiolabeling method for detection of T cell receptor glycoproteins bearing immature and mature N-linked glycans.

The antigen receptor expressed on most T lymphocytes, the T cell receptor (TCR), is a multisubunit complex containing TCR alpha,beta and CD3-gamma,delta, epsilon and zeta chains, in the form alphabetadeltaepsilongammaepsilonzetazeta. The intracellular transport of TCR proteins is routinely measured by the extent of processing of N-linked glycan chains present on TCR alpha,beta and CD3 gamma,delta subunits, which are converted from immature (high mannose) oligosaccharides in the endoplasmic reticulum (ER) to mature (complex type) species within the Golgi complex. In the current study, a radiolabeling method is described that is useful for the study of TCR glycoproteins bearing immature and mature N-linked oligosaccharide chains. Specifically, we report the use of [3H] galactose as a radioactive tracer of TCR proteins containing glucose and galactose residues, present in immature and mature N-linked oligosaccharides, respectively. This technique is rapid, simple, and sensitive, and provides a unique approach for studying the processing and subcellular localization of T cell receptor proteins.

Influence of N-glycan chain length on chaperone association and intracellular transport of major histocompatibility complex class I proteins.

Recent studies demonstrate that processing of N-linked glycans plays an important role in the quality control of major histocompatibility complex (MHC) class I transport from the endoplasmic reticulum (ER) to the Golgi complex and beyond. Here, we investigated the importance of oligosaccharide chain length on the association of MHC class I proteins with molecular chaperones and their intracellular transport from the ER to the Golgi. These data show that calnexin interaction with class I proteins having truncated N-glycans was reduced compared to normal class I molecules, whereas the assembly of class I with calreticulin and TAP was unperturbed by N-glycan chain length. Additionally, these results demonstrate that class I proteins containing truncated N-glycans showed decreased detachment from calreticulin and TAP relative to class I proteins bearing typical oligosaccharides. Taken together, these studies show that N-glycan chain length is an important determinant for the quality control of newly synthesized MHC class I proteins in the ER.

Distinct but dispensable N-glycosylation of human CD69 proteins.

Human CD69 is uniquely glycosylated at typical (Asn-X-Ser/Thr) and atypical (Asn-X-Cys) motifs, which represents the molecular basis for the formation of CD69 homodimers and heterodimers. Here we examined the importance of N-glycosylation for the assembly and intracellular transport of CD69 proteins using mutant CD69 molecules that specifically lack typical and atypical N-glycan attachment motifs. These studies verify the importance of Cys residues in atypical triplet sequences for N-glycan addition to human CD69 proteins in the endoplasmic reticulum (ER). In addition, these data demonstrate that monoglycosylated CD69 proteins (bearing N-glycans exclusively at atypical or typical sites) and aglycosylated CD69 molecules (lacking N-glycans) efficiently dimerize in the ER and have similar stability as wild-type CD69 molecules. Finally, these results show that CD69 proteins lacking atypical or typical N-glycan addition sites are transported to the plasma membrane.

Immunohistochemically detecting target antigens in patient biopsies for tailoring monoclonal antibody based cancer therapy.

Immunohistochemical analysis of biopsies, cytology specimens or surgical resection specimens using antibodies directed towards tumor-associated antigens, lineage or differentiation antigens is a technique often used by surgical pathologists to aid in establishing the correct histologic classification of malignant tumors. With the proliferation of experimental approaches to cancer treatment using monoclonal antibodies as targeting agents, it is anticipated that surgical pathologists will increasingly be receiving requests from clinicians to define the antigen profile in biopsy specimens, even when not necessary to render the correct tumor classification. Clinicians may use the immunohistochemically delineated antigen profiles provided by surgical pathologists to plan tailored treatment regimens utilizing monoclonal antibodies to the antigens expressed in the tumor biopsy to target anticancer therapeutic agents. Some of the potential problems in such a process might include the differing sensitivities, and perhaps specificities, of the antibodies used for analyzing the surgical pathology biopsy specimens compared to the monoclonal antibodies actually used in vivo. Our approach to this dilemma is to develop murine monoclonal antibodies to tumor-associated antigens that can reliably be used to detect antigens in routinely processed surgical pathology specimens as a starting point for further therapeutic monoclonal antibody development.

Modification of the T cell antigen receptor (TCR) complex by UDP-glucose:glycoprotein glucosyltransferase. TCR folding is finalized convergent with formation of alpha beta delta epsilon gamma epsilon complexes.

Most T lymphocytes express on their surfaces a multisubunit receptor complex, the T cell antigen receptor (TCR) containing alpha, beta, gamma, delta, epsilon, and zeta molecules, that has been widely studied as a model system for protein quality control. Although the parameters of TCR assembly are relatively well established, little information exists regarding the stage(s) of TCR oligomerization where folding of TCR proteins is completed. Here we evaluated the modification of TCR glycoproteins by the endoplasmic reticulum folding sensor enzyme UDP-glucose:glycoprotein glucosyltransferase (GT) as a unique and sensitive indicator of how TCR subunits assembled into multisubunit complexes are perceived by the endoplasmic reticulum quality control system. These results demonstrate that all TCR subunits containing N-glycans were modified by GT and that TCR proteins were differentially reglucosylated during their assembly with partner TCR chains. Importantly, these data show that GT modification of most TCR subunits persisted until assembly of CD3alpha beta chains and formation of CD3-associated, disulfide-linked alpha beta heterodimers. These studies provide a novel evaluation of the folding status of TCR glycoproteins during their assembly into multisubunit complexes and are consistent with the concept that TCR folding is finalized convergent with formation of alpha beta delta epsilon gamma epsilon complexes.

Characterization of the epitope on murine T-cell receptor (TCR) alpha proteins recognized by H28-710 monoclonal antibody.

Antigen recognition by alphabeta T lymphocytes is mediated via the multisubunit T-cell receptor (TCR) complex consisting of invariant CD3-gamma,delta,epsilon, and zeta chains associated with clonotypic TCRalpha,beta molecules. In the current report, we evaluated the molecular basis for recognition of murine TCRalpha proteins by H28-710 monoclonal antibody (MAb), specific for the constant region of murine TCRalpha chains. H28-710 is widely used in the study of the TCR complex as it is the only reagent currently available that recognizes all murine TCRalpha proteins, regardless of their clonotype. These data show that H28-710 is useful for the immunoprecipitation of TCRalpha proteins not associated with CD3 subunits, and that H28-710 effectively recognizes denatured TCRalpha proteins synthesized in several different cell types. Most importantly, these results demonstrate that H28 binding involves a serine/threonine-rich region between amino acids 150-177 on murine TCRalpha polypeptides.

A novel monoclonal antibody against rat LFA-1: blockade of LFA-1 and CD4 augments class II MHC expression on T cells.

Previously, we have shown that myelin basic protein (MBP)-specific Lewis rat GP2.E5/R1 (R1) T cells cultured with antigen and irradiated syngeneic splenocytes (IrrSPL) in the presence of anti-CD4 and LRTC1 monoclonal antibodies (MAbs) become highly effective antigen presenting cells (APC). The purpose of these studies was to identify the ligand for the LRTC1 MAb and to determine whether this MAb affected MBP-stimulated IL-2 production and expression of MHC class II molecules by T cells. In the current studies, we show that the LRTC1 MAb specifically immunoprecipitated molecular species of approximately 95, 150, and 180 kD. Commercially available anti-CD18 (beta2 integrin, beta-chain of LFA-1, MAC-1, and p150, 95) and LRTC1 MAb immunoprecipitated proteins with identical mobilities on 1-D and 2-D SDS-PAGE gels. Moreover, anti-CD18 and LRTC1 immunoprecipitates also showed identical mobilities on 1-D gels after enzymatic cleavage of N-linked oligosaccharides and thereby had the same patterns of differential glycosylation. Anti-CD4 MAb W3/25 and LRTC1 MAb synergistically inhibited T-cell IL-2 mRNA and IL-2 bioactivity, but augmented antigen-stimulated surface I-A on R1 T cells. In conclusion, these studies describe the characteristics of a novel anti-LFA-1 MAb, LRTC1, which should prove useful in studying costimulatory and adhesion pathways among rat leukocytes.

Calnexin association is not sufficient to protect T cell receptor alpha proteins from rapid degradation in CD4+CD8+ thymocytes.

During T cell development, assembly of the mutisubunit T cell receptor (TCR) complex is regulated by the differential stability of newly synthesized TCRalpha molecules, having a half-life of approximately 20 min in immature CD4+CD8+ thymocytes compared with >75 min in mature T cells. The molecular basis for TCRalpha instability in CD4+CD8+ thymocytes is unknown but has been postulated to involve abnormalities in N-glycan processing and calnexin assembly as perturbation of these pathways markedly destabilizes TCRalpha proteins in all other T cell types examined. Here, we compared the processing of TCRalpha glycoproteins and their assembly with calnexin and calreticulin chaperones in CD4+CD8+ thymocytes and splenic T cells. These studies show that TCRalpha glycoproteins synthesized in CD4+CD8+ thymocytes were processed in a similar manner as those made in splenic T cells and that TCRalpha proteins stably associated with calnexin in both cell types. Interestingly, however, TCRalpha association with the calnexin-related molecule calreticulin was decreased in CD4+CD8+ thymocytes compared with splenic T cells. Finally, TCRalpha degradation in CD4+CD8+ thymocytes was impaired by inhibitors of proteasome activity, which was correlated with stabilization of calnexin.TCRalpha complexes. These data demonstrate that calnexin association is not sufficient to protect TCRalpha proteins from rapid degradation in CD4+CD8+ thymocytes, suggesting that additional components of the quality control system of the endoplasmic reticulum operate to ensure the proper folding of nascent TCRalpha glycoproteins.

Calnexin associates with monomeric and oligomeric (disulfide-linked) CD3delta proteins in murine T lymphocytes.

The antigen-binding receptor expressed on most T lymphocytes consists of disulfide-linked clonotypic alphabeta heterodimers noncovalently associated with monomeric CD3gamma,delta,epsilon proteins and disulfide-linked zeta zeta homodimers, collectively referred to as the T cell antigen receptor (TCR) complex. Here, we examined and compared the disulfide linkage status of newly synthesized TCR proteins in murine CD4(+)CD8(+) thymocytes and splenic T cells. These studies demonstrate that CD3delta proteins exist as both monomeric and oligomeric (disulfide-linked) species that differentially assemble with CD3epsilon subunits in CD4(+)CD8(+) thymocytes and splenic T cells. Interestingly, unlike previous results on glucose trimming and TCR assembly of CD3delta proteins in splenic T cells (Van Leeuwen, J. E. M., and K. P. Kearse (1996) J. Biol. Chem. 271, 9660-9665), we found that glucose residues were not invariably removed from CD3delta glycoproteins prior to their assembly with CD3epsilon subunits in CD4(+)CD8(+) thymocytes. Finally, these studies show that calnexin associates with both monomeric and disulfide-linked CD3delta proteins in murine T cells. The data in the current report demonstrate that CD3delta proteins exist as both monomeric and disulfide-linked molecules in murine T cells that differentially associate with partner TCR chains in CD4(+)CD8(+) thymocytes and splenic T cells. These results are consistent with the concept that folding and assembly of CD3delta proteins is a function of their oxidation state.

T-cell receptor purification.

The antigen receptor expressed on most T-lymphocytes (T-cell antigen receptor [TCR]) is a multisubunit complex consisting of at least six different polypeptides (α, ß, γ, δ, ɛ, and ζ), several of which are modified by addition of N-linked oligosaccharide chains Oligosaccharide side chains on TCR glycoproteins undergo well-characterized processing events within the endoplasmic reticulum (ER) and Golgi systems, including removal of mannose residues and subsequent addition of galactose and sialic acid oligosaccharides. In the current chapter, a method is described for the isolation of immature and mature TCR complexes from murine T-lymphocytes using lectin affinity chromatography This technique is rapid, sensitive, and does not disrupt the integrity of assembled TCR complexes.

Multiple dimeric forms of human CD69 result from differential addition of N-glycans to typical (Asn-X-Ser/Thr) and atypical (Asn-X-cys) glycosylation motifs.

CD69 is expressed on the surface of all hematopoietically derived leukocytes and is suggested to function as a multipurpose cell-surface trigger molecule important in the development and activation of many different cell types. Human CD69 contains only a single consensus sequence for N-linked oligosaccharide addition within its extracellular domain (Asn-Val-Thr), yet exists as two distinct glycoforms that are assembled together into disulfide-linked homodimers and heterodimers. The molecular basis for human CD69 heterogeneity has remained elusive. In the current report we show that human CD69 glycoforms are generated before the egress of CD69 proteins from the endoplasmic reticulum to the Golgi and are synthesized under conditions where Golgi processing is inhibited, effectively ruling out the possibility that CD69 heterogeneity results from the differential processing of a single glycosylation site in the Golgi complex. Importantly, these data demonstrate that contrary to current belief, not one but two sites for N-glycan addition exist within the human CD69 extracellular domain and identify the second, "cryptic" CD69 N-glycan attachment site as the atypical Cys-containing glycosylation motif, Asn-Ala-Cys. The results in this study provide a molecular basis for human CD69 heterogeneity and show that multiple dimeric forms of human CD69 result from the variable addition of N-glycans to atypical and typical glycosylation motifs within the CD69 extracellular domain.

Developmentally regulated expression of peanut agglutinin (PNA)-specific glycans on murine thymocytes.

Intrathymic maturation of T lymphocytes is characterized by variable expression of O-linked Gal beta 1,3GalNAc glycans reactive with peanut agglutinin (PNA) lectin. Recent studies on human thymocytes show that conversion from PNA+ to PNA- phenotype is correlated with increased expression of alpha 2,3 O-linked sialyltransferase (ST), which sialylates Gal beta 1,3GalNAc glycans, masking their binding sites for PNA. Interestingly, alpha 2,3 O-linked ST expression is highest within the regions of the thymus containing the most immature and most mature thymocyte subsets, suggesting that PNA-specific glycans are intermittently masked by sialylation during thymic selection processes. Here, we studied expression of PNA receptors on developing thymocytes in the murine system using thymocytes from both normal mice and transgenic mice that are genetically arrested at the early phases of T cell development. Our results confirm and extend recent findings in the human system by showing that murine T cells sequentially progress from PNAlo-->PNAhi-->PNAlo stages during their differentiation within the thymus. In addition, our data demonstrate that a similar set of polypeptides is variably masked by sialylation throughout T cell development.

Reglucosylation of N-linked glycans is critical for calnexin assembly with T cell receptor (TCR) alpha proteins but not TCRbeta proteins.

Association of calnexin with newly synthesized glycoproteins involves recognition of monoglucosylated glycans, generated in the endoplasmic reticulum via initial removal of two glucose (Glc) residues from immature glycan chains by glucosidase enzymes (Glc trimming), or addition of a single Glc residue to fully trimmed glycans by glucosyltransferase enzymes (reglucosylation). While it has been established that creation of monoglucosylated glycans is important for chaperone binding, it is unknown if most proteins require both deglucosylation and reglucosylation for calnexin assembly or if initial Glc trimming is sufficient. Here, we studied the deglucosylation and reglucosylation of two related glycoproteins, the alpha and beta subunits of the T cell receptor (TCR) complex, and their assembly with calnexin in BW thymoma cells. Our data demonstrate that TCRalpha/beta glycoproteins undergo multiple cycles of Glc removal and addition within the endoplasmic reticulum and that numerous reglucosylated proteins assemble with calnexin, including TCRalpha/beta glycoproteins. Importantly, the current study shows that TCRbeta proteins, but not TCRalpha proteins, effectively associate with calnexin under conditions of functional Glc trimming but impaired reglucosylation. These data demonstrate that reglucosylated proteins associate with lectin-like chaperones in vivo and provide evidence that reglucosylation is of differential importance for the association of individual, indeed similar, glycoproteins with calnexin.

Deglucosylation of N-linked glycans is an important step in the dissociation of calreticulin-class I-TAP complexes.

Recent evidence indicates that newly synthesized major histocompatibility complex (MHC) class I proteins interact with calnexin, a transmembrane endoplasmic reticulum protein specific for certain glycoproteins bearing monoglucosylated glycans. Here, we studied the association of newly synthesized class I proteins with calreticulin, a soluble calnexin-related ER protein, in murine T cells. We found that, unlike calnexin-class I interactions, calreticulin assembly with class I proteins was markedly decreased in the absence of beta 2 microglobulin expression and that calreticulin associated with a subset of class I glycoforms distinct from those assembled with calnexin but similar to those bound to TAP (transporter associated with antigen processing) proteins. Finally, these studies show that deglucosylation of N-linked glycans is important for dissociation of class I proteins from both calreticulin and TAP and that the vast majority of newly synthesized class I proteins associated with calreticulin are simultaneously assembled with TAP. The data demonstrate that calnexin and calreticulin chaperones assemble with distinct MHC class I assembly intermediates in the ER and show that glycan processing is functionally coupled to release of MHC class I proteins from peptide transport molecules.

The related molecular chaperones calnexin and calreticulin differentially associate with nascent T cell antigen receptor proteins within the endoplasmic reticulum.

Assembly of the multisubunit T cell antigen receptor (TCR) complex is an intricate process requiring coordinated regulation of at least six different gene products (alpha, beta, gamma, delta, epsilon, and zeta) and the ordered pairing of partner chains within the endoplasmic reticulum (ER). To date, two proteins have been implicated as functioning as molecular chaperones in the assembly of nascent TCR proteins: calnexin, a resident ER transmembrane protein, which associates with all TCR components except zeta, and T cell receptor-associated protein, which selectively associates with CD3gammaepsilon pairs. In this study, we examined the association of calreticulin, a soluble protein with significant sequence homology to calnexin, with newly synthesized TCR proteins. Analogous to calnexin, processing of glycan chains by glucosidase enzymes was required for initial association of TCRalpha and -beta proteins with calreticulin; however, several major differences were noted regarding interaction of calnexin and calreticulin chaperones with TCR proteins. First, TCRalpha and -beta proteins showed prolonged association with calnexin molecules compared with calreticulin; interaction of TCRalpha proteins with calreticulin was particularly transient, with most calreticulin-TCRalpha protein complexes dissociating within 15 min of their initial assembly. Second, we found that, unlike calnexin, which associated with clonotypic TCRalpha and -beta proteins and invariant CD3delta and -epsilon polypeptides, calreticulin associated specifically with clonotypic TCRalpha and -beta proteins. These studies identify calreticulin as a molecular chaperone for nascent clonotypic TCRalpha and -beta proteins and demonstrate that calreticulin and calnexin differentially associate with newly synthesized TCR proteins within the ER.

Identification of CD8 as a peanut agglutinin (PNA) receptor molecule on immature thymocytes.

Differentiation of most T lymphocytes occurs within the thymus and is characterized by variable expression of CD4/CD8 coreceptor molecules, increased surface density of T cell antigen receptor (TCR) alpha beta proteins, and decreased expression of glycan chains recognized by the galactose-specific lectin peanut agglutinin (PNA). Although appreciated for several decades that PNA agglutination is useful for the physical separation of immature and mature thymocyte sub-populations, the identity of specific PNA-binding glycoproteins expressed on immature thymocytes remains to be determined. In the current report, we studied the expression of PNA-specific glycans on immature and mature T cells and used lectin affinity chromatography and immunoprecipitation techniques to characterize PNA-binding glycoproteins on thymocytes. Our data demonstrate that PNA-specific glycans are localized on a relatively small subset of thymocyte surface proteins, several of which were specifically identified, including CD43, CD45, and suprisingly, CD8 molecules. CD8 alpha and CD8 alpha' proteins bound to PNA in the absence of CD8 beta expression showing that O-glycans on CD8 beta glycoproteins are not necessary for PNA binding and that glycosylation of CD8 alpha and CD8 alpha' proteins proceeds effectively in the absence of CD8 beta. Finally, we demonstrate that PNA binding of CD8 is developmentally regulated by sialic acid addition as CD8 proteins from mature T cells bound to PNA only after sialidase treatment. These studies identify CD8 as a PNA receptor molecule on immature thymocytes and show that PNA binding of CD8 on immature and mature T cells is developmentally regulated by sialic acid modification.