An HLA-A2/beta 2-microglobulin/peptide complex assembled from subunits expressed separately in Escherichia coli

Recombinant expression of the beta-subunit of HLA-DR10 for the selection of novel lymphoma targeting molecules

Selective high-affinity ligands (SHALs) were selected as substitutes for monoclonal antibodies (mAbs) to deliver radioisotopes to malignant tumors. Because a SHAL (5 KD) is considerably smaller in comparison to an antibody (150 KD), a significant therapeutic index (TI) enhancement for radioimmunotherapy (RIT) is anticipated. The antibody-antigen (Ab-Ag) model system chosen for the development of SHALs consists of Lym-1, a MAb with proven selectivity in non-Hodgkin's lymphoma (NHL) patients and its well-characterized Ag, the beta subunit of HLA DR10. Whereas Lym-1 is readily available, the subunit of HLA-DR10 is not. Native, heterodimeric (alpha and beta subunits) HLA-DR10 can be purified from Raji cells, which are known to overexpress this Ag. Inconsistent homogeneity between preparations of HLA-DR10 solubilized in the presence of detergents prompted us to express a recombinant form of the beta subunit of HLA-DR10 in Escherichia coli. Negligible production yields (<or=50 microg/L) were achieved by the expression of the full-length protein in a soluble form. By contrast, yields of 240 mg/L were obtained by expressing only the extracellular domain (ED) of the beta subunit of HLA-DR10 in an insoluble form (inclusion bodies). The recovery yield of refolded protein was 75%. Circular dichroism (CD) and Lym-1 binding studies indicated that the recombinant ED of the beta subunit of HLA-DR10 was properly folded. Therefore, this recombinant protein can be used as a surrogate for native heterodimeric HLA DR10 for the in vitro selection of SHALs and related targeting molecules.

Accessory proteins and the assembly of human class I MHC molecules: a molecular and structural perspective

The cell-surface presentation of antigenic peptides by class I major histocompatibility complex (MHC) molecules to CD8+ T-cell receptors is part of an immune surveillance mechanism aimed at detecting foreign antigens. This process is initiated in the endoplasmic reticulum (ER) with the folding and assembly of class I MHC molecules which are then transported to the cell surface via the secretory pathway. In recent years, several accessory proteins have been identified as key components of the class I maturation process in the ER. These proteins include the lectin chaperones calnexin (CNX) and calreticulin (CRT), the thiol-dependent oxidoreductase ERp57, the transporter associated with antigen processing (TAP), and the protein tapasin. This review presents the most recent advances made in characterizing the biochemical and structural properties of these proteins, and discusses how this knowledge advances our current understanding of the molecular events underlying the folding and assembly of human class I MHC molecules in the ER.

Allele- and temperature-dependency of in vitro HLA class I assembly

Allelic variations of in vitro HLA class I assembly have been investigated in both the absence and the presence of binding peptides by flow cytometry using human leukocyte antigen (HLA) class I alpha chains isolated by alkali treatment from cultured HLA homozygous B cells and polystyrene beads coated with anti-HLA class I alpha chain antibodies specific to the C-terminal segment (anti-HLA class I beads). The specificity of assembly was temperature dependent, while the stability of the assembled complex depended on the bound peptide. The efficiency of assembly was allele dependent and primarily ruled by the binding affinity of alpha chains with beta(2)m. Thus, an allele hierarchy could be defined for the binding of HLA-B alpha chain with beta(2)-microglobulin: B7, B18 > B35, B62 > B27, B51. Allele and temperature dependency was found in HLA class I reassembly on acid treated B cells. The HLA class I proteins, reassembled with specific single peptides, could be efficiently transferred to anti-HLA class I beads. These findings would be used to produce microspheres coupled at high surface density with oriented single-peptide loaded HLA class I molecules and also to improve the preparation efficiency of HLA class I tetramers by the use of site-specific biotinylation.

Expression of human recombinant beta 2-microglobulin by Aspergillus nidulans and its activity

The light chain of HLA class I protein (beta 2m) has been expressed in Aspergillus nidulans. The cDNA of beta 2m was modified using the polymerase chain reaction to include overlapping extensions for its subsequent fusion into an Aspergillus vector. This fusion resulted in beta 2m cDNA being flanked by the Aspergillus awamori glucoamylase promoter and the Aspergillus niger glucoamylase terminator. Expression of beta 2m was induced by the addition of starch to the culture medium. In preliminary mass culture trials, 177 micrograms/liter of f beta 2m were obtained in 60-liter fermentations. N-terminal sequencing of purified human beta 2m produced in fungi (f beta 2m) revealed that 28% of the purified protein was of proper sequence and 61% of the protein had an additional serine and lysine residue derived from the C-terminus of the fungal leader. Purified f beta 2m from culture supernatants appeared biochemically similar to beta 2m obtained from human urine (u beta 2m) as seen in immunoblot analysis. Functionally, f beta 2m effectively interacted as a subunit of class I MHC molecules. This was seen both in a sandwich ELISA for detecting properly folded HLA class I heavy chain and in assays showing cell-surface beta 2m exchange into the mouse class I MHC H-2Kd. In these experiments the biological activity of f beta 2m was indistinguishable from u beta 2m. The successful expression of biologically active beta 2m in A. nidulans suggests that fungal systems might be useful for the production of other active components of the HLA class I MHC complex.

A recombinant single-chain HLA-A2.1 molecule, with a cis active beta-2-microglobulin domain, is biologically active in peptide binding and antigen presentation

We have constructed a recombinant single-chain human HLA-A2.1 molecule (from A*0201) with a covalently attached beta 2m. This molecule (MSC beta A2.1) can be detected on the surface of transfected beta 2m- human cells by conformational antibodies W6/32 and BB7.2 and by anti-human beta 2m mAb BM-63. The covalent beta 2m, now a domain of the MSC beta A2.1 molecule, does not rescue endogenous Class I surface expression. Instead, it works in cis to achieve correct folding of the single-chain molecule. Immunoprecipitation shows that MSC beta A2.1 is a 60-kDa molecule with no dissociable beta 2m. The half-life of the MSC beta A2.1 molecule on transfected cell surfaces was as long as that of two-chain HLA-A2.1 molecules. The MSC beta A2.1 molecule was active in presentation of HTLV-I Tax 11-19 peptide and an endogenous peptide to specific CTL. MSC beta A2.1 molecules and wild-type HLA-A2.1 molecules on live cells can bind the HBV core peptide 18-27 with comparable affinities. These results show that MSC beta A2.1 molecules retain the functional ability to present both pulsed and endogenous antigens to the appropriate T cells, and thus may be useful components of antiviral vaccines.

Analysis of MHC-specific peptide motifs. Applications in immunotherapy

The structural features which underlie peptide binding to MHC molecules permit the binding of a diverse array of peptides. Polymorphic residues of class I, and to a lesser extent, class II molecules, determine the peptide selectivities associated with various allomorphs. The motifs which are described here and elsewhere in the literature mainly reflect peptide features which contribute to high affinity binding. While high affinity MHC binding is not an absolute prerequisite for the immunologic relevance of a peptide, motifs provide general guidelines for eliciting and characterizing cellular responses to epitopes presented by a given MHC allomorph or group of related allomorphs. The utility of motifs is underscored by emerging developments in the clinical application of peptides to elicit specific and effective cellular responses.

Protein transfer of preformed MHC-peptide complexes sensitizes target cells to T cell cytolysis

Recombinant GPI-anchored HLA-A2.1 (HLA-A2.1-GPI/beta 2m) was used as a protein transfer vehicle to deliver a hepatitis B virus antigenic peptide to the surfaces of cytotoxic T cell targets. Empty HLA-A2.1-GPI/beta 2m was first produced in D. melanogaster cotransfectants and immunoaffinity purified. Cell coating with HLA-A2.1-GPI/beta 2m was shown to occur rapidly, and to be protein concentration dependent. Protein-transferred HLA-A2.1-GPI/beta 2m effectively presented a hepatitis B virus peptide to peptide-specific HLA-A2.1-restricted T cell clones in cytotoxicity assays. Protein transfer of functional GPI-modified class I MHC-antigenic peptide complexes represents a novel strategy for delivering functional antigenic complexes to cell surfaces that bypasses limitations of gene transfer and permits control of antigenic peptide densities at cell surfaces.

Antigenic peptide binding by class I and class II histocompatibility proteins

The recent determination of the structure of a class II MHC molecule complexed to a specific peptide reveals both similarities and differences with peptide binding by class I MHC.

Flow-cytometric determination of peptide-class I complex formation. Identification of p53 peptides that bind to HLA-A2

A novel class I-peptide-binding assay was developed and used to identify a series of peptides derived from the human p53 tumor-suppressor gene product capable of binding the HLA-A2 class I allele. Brief pH 3.3 acid treatment of human cell lines rapidly denatures pre-existing class I complexes, as detected by loss of binding of conformation-dependent mAbs, leaving only free class I heavy chains associated with the viable cell surface. These heavy chains may be induced to refold and be recognized by antibodies (in 2-4 hours) when acid-treated cells are coincubated with exogenous beta 2-microglobulin and peptides capable of binding the relevant class I allele examined. This assay, with a detection limit of 1-10 nM peptide, was used to screen the capacity of a panel of nine peptides bearing HLA-A2-binding motifs and derived from the human p53 tumor-suppressor protein sequence. Eight of the nine peptides bound to, and reconstituted, HLA-A2 on acid-treated cells. This assay system will enable the rapid identification of peptides binding to any class I allele, which is the initial prerequisite for elucidating potential CD8+ T-cell epitopes.

The assembly of H2-Kb class I molecules translated in vitro requires oxidized glutathione and peptide

Association of the mouse major histocompatibility complex (MHC) class I heavy chain H2-Kb with mouse beta 2-microglobulin (beta 2m) was studied in an in vitro translation system. Formation of stable class I complexes was found to be dependent on the presence of presentable peptides and oxidized glutathione, which promotes the formation of disulfide bridges. Translocation of peptides into microsomes was demonstrated by showing that a radioiodinated peptide containing an N-glycosylation acceptor site became glycosylated. Class I complex formation was observed only when heavy chains and beta 2m were translated simultaneously, and thus occurs in the microsomes and not after their solubilization. However, peptide binding takes place only after solubilization of the microsomes. The class I complexes translated in vitro show the same specificity and length preference for peptides as their counterparts in RMA-S cells. Assembly of in vitro translated class I complexes was found to occur also in the absence of peptides, resulting in the formation of unstable molecules that are stabilized by incubation with peptides.

Putting together an MHC class I molecule

Formation of MHC class I complexes involves proper folding of the subunits, their assembly and interaction with peptides. Several proteins contributing to this process have been described, but a number of questions remain, in particular those concerning early folding steps and interactions with peptide in the course of biosynthesis.

A recombinant, soluble, single-chain class I major histocompatibility complex molecule with biological activity

Heterodimeric class I major histocompatibility complex molecules, which consist of a 45-kDa heavy-chain and a 12-kDa beta 2-microglobulin (beta 2m) light chain, bind endogenously synthesized peptides for presentation to antigen-specific T cells. We have synthesized a gene encoding a single-chain, soluble class I molecule derived from mouse H-2Dd, in which the carboxyl terminus of beta 2m is linked via a peptide spacer to the amino terminus of the heavy chain. The chimeric protein is secreted efficiently from transfected L cells, is thermostable, and when loaded with an appropriate antigenic peptide, stimulates an H-2Dd-restricted antigen-specific T-cell hybridoma. Thus, functional binding of peptide does not require the complete dissociation of beta 2m, implying that a heavy chain/peptide complex is not an obligate intermediate in the assembly of the heavy-chain/beta 2m/peptide heterotrimer. Single-chain major histocompatibility complex molecules uniformly loaded with peptide have potential uses for structural studies, toxin or fluor conjugates, and vaccines.