Maintenance of TCR clonality in T cells expressing genes for two TCR heterodimers.

T cell receptor (TCR) allelic exclusion is believed to be primarily mediated by suppression of further recombination at the TCR locus after the expression of a functional TCR protein. Genetic allelic exclusion has been shown to be leaky for the beta chain and, more commonly, for the alpha chain. Here, we demonstrate an additional mechanism by which T cells can maintain monoclonality. T cells from double TCR transgenic mice express only one or the other of the two available TCRs at the cell surface. This "functional allelic exclusion" is apparently due to control of the TCR assembly process because these T cells express RNA and protein for all four transgenic TCR proteins. Lack of cell surface expression of the second TCR may be controlled by a failure to assemble the TCR heterodimer.

The tetraspan protein CD82 is a resident of MHC class II compartments where it associates with HLA-DR, -DM, and -DO molecules.

In specialized APCs, MHC class II molecules are synthesized in the endoplasmic reticulum and transported through the Golgi apparatus to organelles of the endocytic pathway collectively called MHC class II compartments (MIICs). There, the class II-associated invariant chain is degraded, and peptides derived from internalized Ag bind to empty class II in a reaction that is facilitated by the class II-like molecule HLA-DM. An mAb raised to highly purified, immunoisolated MIICs from human B lymphoblastoid cells recognized CD82, a member of the tetraspan family of integral membrane proteins. Subcellular fractionation, immunofluorescence microscopy, and immunoelectron microscopy showed that CD82 is highly enriched in MIICs, particularly in their internal membranes. Coprecipitation analysis showed that CD82 associates in MIICs with class II, DM, and HLA-DO (an inhibitor of peptide loading that binds DM). Similar experiments showed CD63, another tetraspan protein found in MIICs, also associates with these molecules in the compartment and that CD82 and CD63 associate with each other. Preclearing experiments demonstrated that both CD82 and CD63 form complexes with DM-associated class II and DM-associated DO. The ability of CD82 and CD63 to form complexes with class II, DM, and DO in MIICs suggests that the tetraspan proteins may play an important role in the late stages of MHC class II maturation.

Subtle conformational changes induced in major histocompatibility complex class II molecules by binding peptides.

Intracellular trafficking of major histocompatibility complex (MHC) class II molecules is characterized by passage through specialized endocytic compartment(s) where antigenic peptides replace invariant chain fragments in the presence of the DM protein. These changes are accompanied by structural transitions of the MHC molecules that can be visualized by formation of compact SDS-resistant dimers, by changes in binding of mAbs, and by changes in T cell responses. We have observed that a mAb (25-9-17) that is capable of staining I-Ab on the surface of normal B cells failed to interact with I-Ab complexes with a peptide derived from the Ealpha chain of the I-E molecule but bound a similar covalent complex of I-Ab with the class II binding fragment (class II-associated invariant chain peptides) of the invariant chain. Moreover, 25-9-17 blocked activation of several I-Ab-reactive T cell hybridomas but failed to block others, suggesting that numerous I-Ab-peptide complexes acquire the 25-9-17(+) or 25-9-17(-) conformation. Alloreactive T cells were also able to discriminate peptide-dependent variants of MHC class II molecules. Thus, peptides impose subtle structural transitions upon MHC class II molecules that affect T cell recognition and may thus be critical for T cell selection and autiommunity.

Quantitative defect in staphylococcal enterotoxin A binding and presentation by HLA-DM-deficient T2.Ak cells corrected by transfection of HLA-DM genes.

HLA-DM facilitates peptide acquisition by MHC class II proteins within the endosomes of APC by facilitating release of invariant chain peptide intermediates (CLIP) from the class II molecules. T2 cells have a deletion in the MHC II region which deletes HLA-DM and MHC II genes. T2 cells transfected with MHC class II proteins are defective in protein presentation, a defect that is corrected by HLA-DM transfection. Here we show that T2 cells transfected with Ak are also impaired in binding and presentation of the superantistaphylococcal enterotoxin A and that HLA-DM transfection corrects this defect. The poor ability of SEA to bind to Ak on DM-deficient cells is somewhat surprising since Ak has a low affinity for CLIP and is not predominantly occupied with CLIP on T2 cells compared to wide-type APC. These data suggest an influence of HLA-DM on the structure or composition of the Ak/peptide complex beyond its role in the release of invariant chain peptides.

Negative regulation by HLA-DO of MHC class II-restricted antigen processing.

HLA-DM is a major histocompatibility complex (MHC) class II-like molecule that facilitates antigen processing by catalyzing the exchange of invariant chain-derived peptides (CLIP) from class II molecules for antigenic peptides. HLA-DO is a second class II-like molecule that physically associates with HLA-DM in B cells. HLA-DO was shown to block HLA-DM function. Purified HLA-DM-DO complexes could not promote peptide exchange in vitro. Expression of HLA-DO in a class II+ and DM+, DO- human T cell line caused the accumulation of class II-CLIP complexes, indicating that HLA-DO blocked DM function in vivo and suggesting that HLA-DO is an important modulator of class II-restricted antigen processing.

HLA-DM interactions with intermediates in HLA-DR maturation and a role for HLA-DM in stabilizing empty HLA-DR molecules.

Major histocompatibility complex (MHC) class II-positive cell lines which lack HLA-DM expression accumulate class II molecules associated with residual invariant (I) chain fragments (class II-associated invariant chain peptides [CLIP]). In vitro, HLA-DM catalyzes CLIP dissociation from class II-CLIP complexes, promoting binding of antigenic peptides. Here the physical interaction of HLA-DM with HLA-DR molecules was investigated. HLA-DM complexes with class II molecules were detectable transiently in cells, peaking at the time when the class II molecules entered the MHC class II compartment. HLA-DR alpha beta dimers newly released from I chain, and those associated with I chain fragments, were found to associate with HLA-DM in vivo. Mature, peptide-loaded DR molecules also associated at a low level. These same species, but not DR-I chain complexes, were also shown to bind to purified HLA-DM molecules in vitro. HLA-DM interaction was quantitatively superior with DR molecules isolated in association with CLIP. DM-DR complexes generated by incubating HLA-DM with purified DR alpha beta CLIP contained virtually no associated CLIP, suggesting that this superior interaction reflects a prolonged HLA-DM association with empty class II dimers after CLIP dissociation. Incubation of peptide-free alpha beta dimers in the presence of HLA-DM was found to prolong their ability to bind subsequently added antigenic peptides. Stabilization of empty class II molecules may be an important property of HLA-DM in facilitating antigen processing.

HLA-DM is localized to conventional and unconventional MHC class II-containing endocytic compartments.

HLA-DM molecules remove invariant (Ii) chain peptides from newly synthesized MHC class II complexes. Their localization may thus delineate compartments, e.g., MIIC, specialized for loading peptides onto class II molecules. In murine A20 B cells, however, DM is not restricted to specialized endosomal class II-containing vesicles (CIIV). Although DM was found in CIIV, it was also found throughout the endocytic pathway, principally in lysosomes devoid of class II molecules. In human lymphoblasts, HLA-DM was found in structures indistinguishable from late endosomes or lysosomes, although in these cells the lysosomes contained MHC class II molecules. Thus, the distribution of HLA-DM does not necessarily identify specialized class II compartments. Many "MIIC" may represent conventional lysosomes that accumulate MHC class II and HLA-DM in a number of cell types.

Trafficking of major histocompatibility complex class II molecules through intracellular compartments containing HLA-DM.

The endosomal site(s) where MHC class II molecules become competent to bind antigenic peptide has not been completely characterized. We identified endocytic compartments through which newly synthesized MHC class II molecules move prior to their expression on the plasma membrane. The compartments co-sediment with lysosomes in the most dense regions of Percoll gradients. The appearance of proteolytic fragments of the invariant chain (I chain), namely leupeptin-induced proteins (LIPs) and class-II-associated invariant chain peptides (CLIP), in this region of the gradient suggests that the release of MHC class II molecules from I chain association occurs within these vesicles. The formation of SDS-stable alpha beta dimers indicated that MHC class II molecules contained within these compartments are receptive to peptide binding. A majority of the HLA-DM protein was found in the same region of the Percoll gradient, consistent with its established function in MHC class-II-restricted antigen presentation. Immunoelectron micrographs of dense-sedimenting compartments indicated that I chain, MHC class II, and DM molecules are contained within both multivesicular and multilamellar vesicles. The final stages of I chain dissociation from MHC class II molecules and DM-mediated peptide loading probably occur in these compartments.

HLA-DM induces CLIP dissociation from MHC class II alpha beta dimers and facilitates peptide loading.

Human leukocyte antigen DM (HLA-DM) molecules are structurally related to classical MHC class II molecules and reside in the lysosome-like compartment where class II-restricted antigen processing is thought to occur. Mutant cell lines lacking HLA-DM are defective in antigen processing and accumulate class II molecules associated with a nested set of invariant chain-derived peptides (class II-associated invariant chain peptides, CLIP). Here we show that HLA-DM catalyzes the dissociation of CLIP from MHC class II-CLIP complexes in vitro and facilitates the binding of antigenic peptides. The reaction has an acidic pH optimum, consistent with its occurrence in a lysosome-like compartment in vivo. Antibody blocking experiments suggest that a transient interaction between HLA-DM and the MHC class II-CLIP complex is required.

Assembly and intracellular transport of HLA-DM and correction of the class II antigen-processing defect in T2 cells.

MHC class II molecules expressed in T2 cells fail to acquire a normal complement of endocytically generated peptides. The defect is repaired by introducing HLA-DMA and HLA-DMB cDNA expression vectors, determined by the restoration of SDS stability of class II alpha beta dimers, restoration of a normal conformation for HLA-DR3 as detected by a monoclonal antibody, and by a reduction in class II-associated invariant chain peptides. The intracellular distribution of class II and invariant chain molecules is also restored to that of wild-type cells. The HLA-DMA and HLA-DMB products appear to form a heterodimer that, although transported at least to the medial Golgi, is not expressed at the cell surface. These findings are consistent with HLA-DM functioning intracellularly to facilitate class II-restricted antigen processing.

Mutational analysis of active site contact residues in anti-fluorescein monoclonal antibody 4-4-20.

The contribution to high affinity Fl binding by each crystallographically defined Mab 4-4-20 (Ka = 1.7 x 10(10) M-1; Qmax = 90%) ligand contact residue (L27dHis, L32Tyr, L34Arg, L91Ser, L96Trp and H33Trp) has been determined by site-specific mutagenesis studies. All six antigen contact residues were changed to Ala in the single-chain derivative of Mab 4-4-20 and following expression in E. coli, denaturation, refolding and purification, each SCA mutant was characterized in terms of Fl binding affinity, Qmax, lambda max and idiotype. Results demonstrated that Ala substitutions at each ligand contact residue reduced the binding affinities and quenching maxima for all residues except L27d which retained wild type characteristics. The SCA TyrL32Ala, SerL91Ala and TrpH33Ala mutants exhibited binding affinities that were approximately 1000-fold lower than the wild type value and greatly reduced Qmax values. Additionally, other amino acid substitutions were performed at three of the six antigen contact residues (L91Ser, L96Trp and H33Trp) to further evaluate the role of each in Fl binding. Therefore, the following mutations were constructed and characterized: SerL91Asn, TrpL96Tyr, TrpL96Phe, TrpL96Leu, TrpH33Tyr and TrpH33Phe. Results of site-specific mutagenesis studies are discussed in terms of Mab active site structure and suggest that L32Tyr, L91Ser and H33Trp are important for high affinity Fl binding and efficient Fl quenching.

Elicitation of distinct populations of monoclonal antibodies specific for the variable domains of monoclonal anti-fluorescein antibody 4-4-20.

Armenian hamsters were immunized with non-liganded, partially liganded or affinity-labeled anti-fluorescein Mab 4-4-20. Seventeen hybridoma producing monoclonal anti-4-4-20 antibodies were characterized from chemically-mediated fusions of immune hamster lymphocytes with murine Sp2/O-Ag14 myeloma cells. Distinct populations of anti-4-4-20 monoclonal antibodies were isolated from hamsters receiving immunizations with partially liganded Mab 4-4-20 relative to those receiving affinity-labeled 4-4-20. Two of the three monoclonal antibodies produced in response to partially liganded 4-4-20 were inhibited in their interaction with 4-4-20 by fluorescyl ligand. These two clones, 1F4 and 1B7, recognized unique epitopes on the 4-4-20 molecules, as demonstrated by non-reactivity with members of the 4-4-20 idiotype family. Additionally, 1F4 and 1B7 demonstrated the ability to delay the association of fluorescein with Mab 4-4-20. The 14 characterized non-ligand-inhibitable Mabs elicited to affinity-labeled 4-4-20 were classified into four separate groups based on various binding properties with members of the 4-4-20 idiotype family and binding to resolved H- and L-chains in a western blot. Members of three of the four groups showed strong reactivity with both 04-01 Ig and 04-01 SCA, which utilizes the same L-chain as Mab 4-4-20. Six non-ligand-inhibitable Mabs, 4A6, P1E11, 3A5-1, 2C3, 2C4, and 1A4, delayed the dissociation rate of ligand from Mab 4-4-20 and mutant 4-4-20 SCA L32phe.

Construction, characterization, and selected site-specific mutagenesis of an anti-single-stranded DNA single-chain autoantibody.

Single-chain antibodies are comprised of immunoglobulin light and heavy chain variable domains joined through a polypeptide linker. A single-chain autoantibody, containing the 14-amino acid 212-polypeptide linker (GSTSGSGKSSEGKG), was constructed based on the light and heavy chain variable region gene sequences of anti-single-stranded DNA autoantibody BV04-01 (IgG2b, kappa). Following protein expression in Escherichia coli, denaturation, refolding, and affinity purification, single-chain autoantibody 04-01 binding with single-stranded DNA and poly(dT) was characterized in solid-phase and solution-phase assays. Homopolymer ligand binding results demonstrated that single-chain autoantibody 04-01 possessed anti-DNA binding properties similar to BV04-01 IgG and Fab fragments. Based on x-ray crystallographic analyses of BV04-01, site-specific mutagenesis studies were conducted on 2 residues (L32Tyr and H100aTrp) involved in aromatic stacking interactions with the middle thymidine of a (dT)3 ligand.

Comparative circular dichroism studies of an anti-fluorescein monoclonal antibody (Mab 4-4-20) and its derivatives.

This study presents circular dichroism (CD) spectra of a high-affinity monoclonal anti-fluorescein antibody (Mab 4-4-20), its Fab fragments, and corresponding single-chain antibody (SCA). In the region 200-250 nm, the differences in the CD spectra between these proteins reflect the uneven distribution of chromophores (tryptophan and tyrosine) rather than a major conformational change. On the basis of near-UV CD spectra, binding of the hapten fluorescein to these protein antibodies elicits an increased asymmetry in the microenvironment of the chromophoric residues in contact with the hapten and also perturbs the interface between VL and VH domains. The hapten-binding site provides a chiral microenvironment for fluorescein that elicits a pronounced induced fluorescein CD spectrum in both the visible and UV regions. In contrast to the parent molecules, SCA is thermolabile. Our results demonstrate that (1) UV CD spectra are useful for assessing the chromophoric microenvironment in the binding portion of antibodies and (2) the extrinsic fluorescein hapten CD spectra provide information about the interaction of hapten with the binding pocket.

Molecular stabilization effects of interactions between anti-metatype antibodies and liganded antibody.

Anti-metatype antibodies have been described as antibodies which recognize ligand-induced conformational changes in the antibody variable region. Additionally, anti-metatype antibodies, produced by multiple immunizations with liganded high affinity monoclonal anti-fluorescein antibody 4-4-20, enhanced the lifetime of monoclonal antibody 4-4-20-fluorescein complex. To better understand the mechanism of the delayed dissociation rate, deuterium oxide was used to probe the liganded active site. The rate and extent of deuterium oxide-mediated fluorescence enhancement of bound ligand served to monitor the conformational dynamics of the active site in the presence and absence of anti-metatype antibodies. Results showed that anti-metatype antibodies reduced the rate and extent of deuterium oxide-mediated fluorescence enhancement of 4-4-20, a single-chain derivative of 4-4-20 (consisting of the variable domains and a polylinker), and idiotypically related monoclonal anti-fluorescein antibodies suggesting that anti-metatype stabilized the liganded active site. Size exclusion liquid chromatography was utilized to isolate the liganded antibody-anti-metatype complex. Liganded single chain antibody 4-4-20 was mixed with 10-fold molar excess anti-metatype Fab fragments, and a major complex eluted with an apparent M(r) 249,000. The apparent molecular weight of this complex inferred that one liganded single chain antibody was bound by five antimetatype Fab fragments. Spectral analysis confirmed these results and the characteristic delayed rate of ligand dissociation was also observed for the isolated complex. The results suggest that anti-metatype antibodies stabilize the liganded conformation by forming a large, stable, macromolecular complex.

Construction, characterization, and mutagenesis of an anti-fluorescein single chain antibody idiotype family.

In addition to crystallographic studies that determined antigen contact residues for monoclonal anti-fluorescein (Fl) antibody 4-4-20 (Ka = 2.5 x 10(10) M-1), primary structure comparisons revealed idiotypically cross-reactive monoclonal antibodies (mAbs) 9-40 (Ka = 4.4 x 10(7) M-1), 12-40 (Ka = 4.0 x 10(8) M-1), and 5-14 (Ka = 2.4 x 10(8) M-1) possessed identical Fl contact residues, with the exception of L34His for L34Arg. Site-specific mutagenesis of single chain antibody (SCA) 4-4-20 in which L34Arg was changed to L34His resulted in approximately 1000- and 3-fold decreases in binding affinity and Qmax (maximum quenching of bound Fl), respectively, which suggested that L34Arg was directly involved in increased binding affinity and fluorescence quenching. Therefore, substitution of Arg for His at residue L34 in mAbs 9-40, 12-40, and 5-14 should result in increased binding affinity and Qmax. To facilitate site-specific mutagenesis studies, single chain derivatives of mAbs 9-40, 12-40, and 5-14 were constructed. Following expression in Escherichia coli, characterization of the SCAs demonstrated that when compared with the respective parental mAb, the SCAs possessed identical binding affinities and similar Qmax and lambda max (absorption profiles of bound Fl) values. These results validated SCA 9-40, 12-40, and 5-14 for use in site-directed mutagenesis studies. Results of mutagenesis studies indicated that substitution of L34Arg into the active sites of 9-40, 12-40, and 5-14 was not enough to produce 4-4-20-like binding characteristics. Therefore, the following single chain mutants were constructed: 9-40L34Arg/L46Val, 12-40L34Arg/L46Val and 5-14L34Arg/L46Val, 9-40L34Arg/L46Val/H101Asp and 4-4-20H101Ala. Results demonstrated that these mutations were not able to render the mutant SCAs with increased binding affinity and fluorescence quenching values. Collectively, these results suggest that the combining sites of mAb 9-40, 12-40, and 5-14 may possess different active site structures than mAb 4-4-20.

Characterization of a single-chain T-cell receptor expressed in Escherichia coli.

Despite progress in defining the nature of major histocompatibility complex products that are recognized by the T-cell antigen receptor, the binding properties and structure of the receptor have not been solved. The primary problem has been the difficulty in obtaining sufficient quantities of active receptor. In this report we show that a single-chain T-cell receptor gene can be expressed in Escherichia coli. The protein consists of the variable (V) regions of the alpha and beta chains (V alpha and V beta) encoded by the cytotoxic T-lymphocyte clone 2C (a H-2b anti-H-2d alloreactive cell line) linked by a 25-amino acid flexible peptide. Solubilized extracts that contain the 27-kDa V alpha 3V beta 8 protein are positive in solid-phase immunoassays with the anti-V beta 8 antibody KJ16 and the anti-clonotypic antibody 1B2. Approximately 1% of the protein can be specifically purified on a 1B2-conjugated column. These results indicate that a fraction of the protein is able to fold into a native conformation and that single-chain proteins should be useful not only as immunogens for eliciting anti-T-cell receptor antibodies but in the study of T-cell receptor structure and function.

Autologous anti-metatype immune response in rabbits.

Rabbits hyperimmunized with fluorescyl-conjugated KLH exhibited bound ligand associated with a high affinity circulating IgG anti-fluorescein population. After cessation of immunogen administration the liganded complexes were eventually spontaneously cleared from the circulation. Individual rabbits synthesized autologous anti-metatype antibodies specific for ligand-antibody complexes. Autologous anti-metatype antibodies reacted optimally with autologous liganded anti-fluorescein antibodies. However, cross reactivity was noted with allogenic rabbit liganded antibodies from three affinity-purified pools. An autologous anti-metatype response, reminiscent of autoanti-idiotype responses, has important implications concerning in vivo clearance of antigen-antibody complexes and may serve as a model to study immune complex diseases.

Importance of dynamic properties of idiotopes in interactions with anti-Id antibodies.

The concept of fluctuating conformational substates in equilibrium characterizing variable-regions of immunoglobulin idiotypes is discussed in terms of the dynamic properties of idiotopes and their stabilization upon interactions with anti-idiotope antibodies. Uniquely, polyclonal anti-Id antibodies are viewed in cooperative immobilizing interactions with the idiotopes thereby facilitating formation of stable complexes.

Single-chain site-specific mutations of fluorescein-amino acid contact residues in high affinity monoclonal antibody 4-4-20.

Previous crystallographic studies of high affinity anti-fluorescein monoclonal antibody 4-4-20 (Ka = 1.7 x 10(10) M-1) complexed with fluorescyl ligand resolved active site contact residues involved in binding. For better definition of the relative roles of three light chain antigen contact residues (L27dhis, L32tyr and L34arg), four site-specific mutations (L27dhis to L27lys, L32tyr to L32phe, and L34arg to L34lys and L34his) were generated and expressed in single-chain antigen binding derivatives of monoclonal antibody 4-4-20 containing two different polypeptide linkers (SCA 4-4-20/205c, 25 amino acids and SCA 4-4-20/212, 14 amino acids). Results showed that L27dhis and L32tyr were necessary for wild type binding affinities, however, were not required for near-wild type Qmax values (where Qmax is the maximum fluoroscein fluorescence quenching expressed as percent). Tyrosine L32 which hydrogen bonds with ligand was also characterized at the haptenic level through the use of 9-hydroxyphenylfluoron which lacks the carboxyl group to which L32 tyrosine forms a hydrogen bond. Results demonstrated that wild type SCA and mutant L32phe possessed similar HPF binding characteristics. Active site contact residue L34arg was important for fluorescein quenching maxima and binding affinity (L34his mutant), however, substitution of lysine for arginine at L34 did not have a significant effect on observed Qmax value. In addition, substitutions had no effect on structural and topological characteristics, since all mutants retained similar idiotypic and metatypic properties. Finally, two linkers were comparatively examined to determine relative contributions to mutant binding properties and stability. No linker effects were observed. Collectively, these results verified the importance of these light chain fluorescein contact residues in the binding pocket of monoclonal antibody 4-4-20.