Amyloid precursor-like protein 2 association with HLA class I molecules

Amyloid precursor-like protein 2 (APLP2) is a ubiquitously expressed protein. The previously demonstrated functions for APLP2 include binding to the mouse major histocompatibility complex (MHC) class I molecule H-2K^d and down regulating its cell surface expression. In this study, we have investigated the interaction of APLP2 with the human leukocyte antigen (HLA) class I molecule in human tumor cell lines. APLP2 was readily detected in pancreatic, breast, and prostate tumor lines, although it was found only in very low amounts in lymphoma cell lines. In a pancreatic tumor cell line, HLA class I was extensively co-localized with APLP2 in vesicular compartments following endocytosis of HLA class I molecules. In pancreatic, breast, and prostate tumor lines, APLP2 was bound to the HLA class I molecule. APLP2 was found to bind to HLA-A24, and more strongly to HLA-A2. Increased expression of APLP2 resulted in reduced surface expression of HLA-A2 and HLA-A24. Overall, these studies demonstrate that APLP2 binds to the HLA class I molecule, co-localizes with it in intracellular vesicles, and reduces the level of HLA class I molecule cell surface expression.     

Biochemical complexity of serum HLA class I molecules

Human serum was found to contain a variety of class I-like molecules by Western blotting with anti-class I heavy chain reagents: major bands usually are observed around M _r 44 000, 40 000, and 35 000–37 000. HLA-A24-positive individuals are distinguished by higher serum levels of M _r 44 000 and 40 000 class I-like molecules than those found in HLA-A24-negative individuals. The M _r 44 000 serum molecules are probably intact class I molecules that have been shed from the cell membrane, because they contain both a transmembrane segment (TM), as deduced from detergent-binding experiments, and a cytoplasmic tail (CT), as inferred from reactivity with an antipeptide serum specific for the cytoplasmic domain of class I antigens (RaCT). The M _r 35 000 and 37 000 molecules contain neither a TM nor a CT region and therefore are probably proteolytic breakdown products of cellular and/or serum M _r 44 000 molecules, although the existence of Q10-like molecules in man cannot be ruled out. The M _r 40 000 molecules do not contain a TM region. M _r 40 000 molecules reactive with the RaCT serum were found in the minority (2/13) of sera tested. We conclude that alternative splicing resulting in a precise excision of the TM exon plays a minor role in the generation of serum HLA class I antigens.Abbreviations used in this paper B2m beta-2 microglobulin - BSA bovine serum albumin - EBV-BLCL Epstein-Barr virus-transformed B lymphoblastoid cell line - mAb monoclonal antibody - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - TCA trichloroacetic acid     

Prediction of promiscuous peptides that bind HLA class I molecules

Promiscuous T-cell epitopes make ideal targets for vaccine development. We report here a computational system, MULTIPRED, for the prediction of peptide binding to the HLA-A2 supertype. It combines a novel representation of peptide/MHC interactions with a hidden Markov model as the prediction algorithm. MULTIPREDis both sensitive and specific, and demonstrates high accuracy of peptide-binding predictions for HLA-A*0201, *0204, and *0205 alleles, good accuracy for *0206 allele, and marginal accuracy for *0203 allele. MULTIPREDreplaces earlier requirements for individual prediction models for each HLA allelic variant and simplifies computational aspects of peptide-binding prediction. Preliminary testing indicates that MULTIPRED can predict peptide binding to HLA-A2 supertype molecules with high accuracy, including those allelic variants for which no experimental binding data are currently available.     

Cytotoxic T lymphocyte recognition of secreted HLA class I molecules

The cytolytic responses of DBA/2 mice against syngeneic transfected P815 mastocytoma cells expressing either membrane-associated (HLA-Cw3) or -secreted hybrid (HLA-Cw3 x H-2 Q10b) molecules were compared. In spite of the absence of serologically detectable hybrid molecules on their plasma membrane, cells secreting these molecules elicited a CTL response similar to that of cells expressing the membrane associated HLA-Cw3 molecules, in terms of both MHC-restriction and peptide specificity. Together with the observation that syngeneic mice were capable of rejecting the injected secreting cells, these results imply that secreted HLA class I molecules can function as minor histocompatibility Ag and suggest that processing of both the membrane-bound and the -secreted forms of a protein may follow common or overlapping pathways.     

Species-specific structural differences in the alpha 1 + alpha 2 domains determine the frequency of murine cytotoxic T cell precursors stimulated by human and murine class I molecules

The frequency of murine CTL precursors (CTLp) that recognize the human histocompatibility Ag HLA-A2 and HLA-B7 was measured and found to be approximately two orders of magnitude lower than the frequency of CTLp that recognize murine H-2 alloantigens. The possible contribution of other cell surface molecules to this difference in response was addressed by expression of the H-2Ld molecule on a human cell and the HLA-B7 molecule on a murine cell. It was found that both human and murine H-2Ld expressing cells elicited comparable levels of H-2Ld specific CTL. Although murine HLA-B7 positive cells stimulated a higher frequency of HLA-B7-specific CTLp than did human cells, this appeared to be largely due to stimulation of CTLp that recognized HLA-B7 in the context of H-2 molecules; consequently, it was concluded that the difference in the frequency of murine CTLp elicited by human and murine class I Ag is due to species specific structural differences in these molecules. The regions of the class I molecule that were responsible for this difference were mapped using chimeric class I molecules constructed to replace domains of the human molecule with their murine counterparts. It was found that the frequency of CTLp is controlled by structures within the alpha 1 and alpha 2 domains of the molecule. These results are discussed in the light of models for T cell recognition of class I Ag and the diversification of the T cell receptor repertoire.     

Selective binding of collagen subtypes by integrin alpha 1I, alpha 2I, and alpha 10I domains

Four integrins, namely alpha(1)beta(1), alpha(2)beta(1), alpha(10)beta(1), and alpha(11)beta(1), form a special subclass of cell adhesion receptors. They are all collagen receptors, and they recognize their ligands with an inserted domain (I domain) in their alpha subunit. We have produced the human integrin alpha(10)I domain as a recombinant protein to reveal its ligand binding specificity. In general, alpha(10)I did recognize collagen types I-VI and laminin-1 in a Mg(2+)-dependent manner, whereas its binding to tenascin was only slightly better than to albumin. When alpha(10)I was tested together with the alpha(1)I and alpha(2)I domains, all three I domains seemed to have their own collagen binding preferences. The integrin alpha(2)I domain bound much better to fibrillar collagens (I-III) than to basement membrane type IV collagen or to beaded filament-forming type VI collagen. Integrin alpha(1)I had the opposite binding pattern. The integrin alpha(10)I domain was similar to the alpha(1)I domain in that it bound very well to collagen types IV and VI. Based on the previously published atomic structures of the alpha(1)I and alpha(2)I domains, we modeled the structure of the alpha(10)I domain. The comparison of the three I domains revealed similarities and differences that could potentially explain their functional differences. Mutations were introduced into the alphaI domains, and their binding to types I, IV, and VI collagen was tested. In the alpha(2)I domain, Asp-219 is one of the amino acids previously suggested to interact directly with type I collagen. The corresponding amino acid in both the alpha(1)I and alpha(10)I domains is oppositely charged (Arg-218). The mutation D219R in the alpha(2)I domain changed the ligand binding pattern to resemble that of the alpha(1)I and alpha(10)I domains and, vice versa, the R218D mutation in the alpha(1)I and alpha(10)I domains created an alpha(2)I domain-like ligand binding pattern. Thus, all three collagen receptors appear to differ in their ability to recognize distinct collagen subtypes. The relatively small structural differences on their collagen binding surfaces may explain the functional specifics.     

Possible association between IL-2 receptors and class I HLA molecules on T cells

In the process of evaluating murine hybridomas for an antibody to the beta-subunit of the IL-2R (p70) we identified an antibody that immunoprecipitated a 55- to 57-kDa complex from cross-linked lysates. We demonstrate that this complex is composed of IL-2 (15.5 kDa) cross-linked to the H chain of HLA class I (40 to 42 kDa), suggesting a molecular interaction between HLA class I molecules and IL-2R. Although the exact role of this association remains to be determined, the specific cross-linking of IL-2 to HLA class I Ag is intriguing in view of published claims for a role of HLA class I in OKT3-induced lymphocyte proliferation and in NK cell lytic activity.     

Impact of peptides on the recognition of HLA class I molecules by human HLA antibodies

MHC class I molecules expressed on cell surfaces are composed of H chain, beta2-microglobulin and any of a vast array of peptides. The role of peptide in the recognition of HLA class I by serum HLA Abs is unknown. In this study, the solid-phase assay of a series (n = 11) of HLA-A2-reactive, pregnancy-induced, human mAbs on a panel (n = 12) of recombinant monomeric HLA-A2 molecules, each containing a single peptide, revealed peptide selectivity of the mAbs. The flow cytometry membrane staining intensities on the HLA-A2-transduced cell line K562, caused by these mAbs, correlated with the number of monomer species detected by the mAbs. Flow cytometry staining on HLA-A2-bearing cell lines of a variety of lineages was indicative of tissue selectivity of these HLA-A2 mAbs. This tissue selectivity suggests that the deleterious effect on allografts is confined to alloantibodies recognizing only HLA class I loaded with peptides that are derived from tissue-specific and household proteins. Since Abs that are only reactive with HLA loaded with irrelevant peptides are expected to be harmless toward allografts, the practice of HLA Ab determination on lymphocyte-derived HLA deserves reconsideration.     

Soluble HLA class I molecules: biological significance and clinical implications

Soluble class I human leukocyte antigens (sHLAs) have been detected in serum, sweat, lymphatic fluid, urine and cerebrospinal fluid. Their biological function has, however, remained a puzzle. The physiological concentration of sHLA varies more than tenfold depending on the phenotype of the individual, and is significantly upregulated in various diseases and during inflammation. This suggests that sHLAs might serve as a marker of pathological changes. Recent experiments have shown that, in vitro, sHLAs can modulate T-cell reactivity and induce cell-activated apoptosis, implicating sHLAs in the induction and maintenance of peripheral tolerance. Therefore, sHLAs have the therapeutic potential to induce tolerance to transplants.     

Exon shuffling in vivo can generate novel HLA class I molecules

The human class I histocompatibility molecule HLA-Aw69 has serological and structural properties which suggested it was a hybrid of the allelic products HLA-A2 and HLA-Aw68. We have now isolated three genes for HLA-Aw69 and one gene for HLA-Aw68. The sequences of exons encoding the entire extracellular portion of the molecule and of intron 2 have been determined. Their comparison with the published sequence of HLA-A2 proves that HLA-Aw69 is a hybrid molecule with complete identity to HLA-Aw68 in the alpha 1 domain and with HLA-A2 in the alpha 2 and alpha 3 domains. This comparison also localised regions involved in the epitopes recognised by monoclonal antibodies. The three HLA-Aw69 genes obtained from unrelated individuals of diverse ethnic backgrounds are identical. All results are consistent with HLA-Aw69 having arisen by a single reciprocal recombination event between the HLA-Aw68 and HLA-A2 genes somewhere in a region of 86 bp about the 3' donor splice site of exon 2. Estimates of the silent mutation rate in HLA genes suggest this event occurred not more than 330 000 years ago. Intra-allelic reciprocal recombination thus represents a further mechanism in addition to gene conversion for the generation of novel class I histocompatibility alleles.     

IFN increases class I MHC antigen expression on adenovirus-infected human cells without inducing resistance to natural killer cell killing.

It has been previously shown that unstimulated NK cells cannot preferentially lyse adenovirus serotypes 2 and 5-infected human cells. In this study, the ability of IFN to promote the selective NK cell-mediated lysis of adenovirus-infected human cells was determined. The relationship between target cell susceptibility to NK cell-mediated killing and class I Ag expression was also analyzed through the use of adenovirus serotype 2 and 5 mutants that do not make the adenovirus early region 3 19-kDa class I binding protein. IFN induced the selective lysis of adenovirus serotype 2 and 5-infected human cells by activating NK cells (IFN-alpha) and protecting uninfected, but not adenovirus-infected cells, from NK cell-mediated lysis (IFN-gamma). IFN-gamma increased the expression of class I Ag on the surface of cells infected with the adenovirus early region 3 deletion mutants, dl327 or dl801, to a level equal to or greater than that expressed on uninfected cells. Despite the increased expression of class I Ag, IFN-gamma could not protect these adenovirus-infected cells from NK cell-mediated lysis. Thus, dl327 or dl801 infection prevented IFN-gamma's induction of cytolytic resistance to NK cell-mediated killing but left IFN-gamma's induction of class I Ag intact. Surface class I Ag levels were substantially higher on IFN-gamma-treated, dl327-, and dl801-infected cells in comparison to cells infected with wild type adenovirus serotype 5. Again, higher target cell levels of class I Ag did not correlate with increased resistance to NK cell-mediated lysis because there was equivalent NK cell-mediated killing of IFN-gamma-treated adenovirus serotype 5-, dl327-, or dl801-infected cells. Thus, IFN-gamma only protects uninfected cells from NK cell-mediated killing, irrespective of target class I Ag levels, and thereby concentrates NK lytic activity on just adenovirus-infected cells. These data demonstrate that IFN-gamma's ability to protect target cells from NK cell-mediated cytolysis is unrelated to IFN-gamma's induction of surface class I MHC Ag.     

Localization of structural variations distinguishing I-Ak-related molecules to the alpha 1 and beta 1 domains

The structural variations that distinguish the A molecules encoded by wild-derived H-2 complexes which express Ak-related molecules have been localized into the alpha 1 and beta 1 domains by radiochemical sequence analyses of tryptic peptides. The A alpha subunits of B10.STC90 (Akv1) and W12A (Akv2) differ from those of B10.BR (Ak) in two adjacent tryptic peptides spanning positions 43 to 71 in the alpha 1 domain. The A beta subunit of W12A differs from that of B10.BR in two peptides spanning positions 26 to 29 and 95 to 106. Isoleucine and leucine residues present at positions 28 and 95, respectively, in the B10.BR A beta subunit are not found in the corresponding positions in W12A A beta subunits. Both of these A beta sequence variations are in the beta 1 domain. B10.STC90 A beta subunits are identical to those of W12A except for a structural variation in the beta 1 domain affecting the HPLC retention time of a peptide spanning positions 49 to 63. These results suggest that these A molecules are encoded by closely related class II gene alleles which have diversified by the accumulation of discrete mutations within the exons encoding the alpha 1 and beta 1 domains of the A molecule. Our previous functional analyses of these minor variant A molecules have demonstrated that they are readily distinguished with A molecule-specific alloreactive T lymphocytes. Together, these findings suggest that minor structural variations in the alpha 1 and beta 1 domains of the A molecule can dramatically modify the allodeterminants recognized by alloreactive T lymphocytes.     

The N-terminal domains of neuregulin 1 confer signal attenuation

Degradation of activated ERBB receptors is an important mechanism for signal attenuation. However, compared with epidermal growth factor (EGF) receptor, the ERBB2/ERBB3 signaling pair is considered to be attenuation-deficient. The ERBB2/ERBB3 ligands of the neuregulin family rely on an EGF-like domain for signaling and are generated from larger membrane-bound precursors. In contrast to EGF, which is processed to yield a 6-kDa peptide ligand, mature neuregulins retain a variety of segments N-terminal to the EGF-like domain. Here we evaluate the role of the N-terminal domain of neuregulin 1 in signaling and turnover of ERBB2/ERBB3. Our data suggest that whereas the EGF-like domain of neuregulin 1 is required and sufficient for the formation of active receptor heterodimers, the presence of the N-terminal Ig-like domain is required for efficient signal attenuation. This manifests itself for both ERBB2 and ERBB3 but is more pronounced and coupled directly to degradation for ERBB3. When stimulated with only the EGF-like domain, ERBB3 shows degradation rates comparable with constitutive turnover, but stimulation with full-length neuregulin 1 resulted in receptor degradation at rates that are comparable with activated EGF receptor. Most of the enhancement in down-regulation was maintained after replacing the Ig-like domain with a thioredoxin protein of comparable size but different amino acid composition, suggesting that the physical presence but not specific properties of the Ig-like domain are needed. This sequence-independent effect of the N-terminal domain correlates with an enhanced ability of full-size neuregulin 1 to disrupt higher order oligomers of the ERBB3 extracellular domains in vitro.     

A geometric study of the amino acid sequence of class I HLA molecules

 HLA class I alleles are studied by representing them in a metric space where each dimension corresponds to each one of the amino acid positions. Their similarity in reference to their ability to present peptides to T cells is then evaluated by calculating the correlation matrix between the amino-acid-composition tables (or binding affinity tables) for the sets of peptides presented by each allele. This correlation matrix is considered an empirical similarity matrix between HLA alleles, and is modeled in terms of possible structures defined in the metric space of HLA class I amino acid sequences. These geometric structures are adequate models of the peptide-binding data currently available. The following clusters of HLA class I molecules are identified in reference to their ability to present peptides: Cluster I) HLA-A3/ HLA-A11/ HLA-A31/ HLA-A33/ HLA-A68; Cluster II) HLA-B35/ HLA-B51/ HLA-B53/ HLA-B54/ HLA-B7; and Cluster III) HLA-A29/ HLA-B61/HLA-B44; the last cluster showing possible similarities between alleles from different loci. In modeling these natural clusters, the geometric structures with more predictive power confirm the importance of those positions in the peptide-binding groove, particularly those in the B pocket. In addition, other positions (46, 79, 113, 131, 144, and 177) appeared to bear some relevance in determining which peptides can be presented by which HLA alleles. Received: 20 January 1998 / Revised: 30 March 1998     

Human beta 2-microglobulin specifically enhances cell-surface expression of HLA class I molecules in transfected murine cells

Sequential transfections of P815 murine mastocytoma cells with class I gene encoding either HLA-Cw3, HLA-A3, or HLA-B7 H chain and subsequently with a human beta 2-microglobulin gene were performed to evaluate the relative efficiency of human and murine beta 2-microglobulins in promoting the cell-surface expression of HLA-class I molecules. A 6-, 11-, and 40-fold specific enhancement of the cell-surface expression of HLA-Cw3, HLA-A3, and HLA-B7 molecules, respectively, was observed in cells co-transfected with human beta 2-microglobulin gene. This effect was attributed to a more efficient association of HLA H chains with human than with murine beta 2-microglobulin, which apparently allowed a more rapid transport of the HLA molecules from the endoplasmic reticulum to the Golgi apparatus.     

The complementarity-determining region-like loops of CD8 alpha interact differently with beta 2-microglobulin of the class I molecules H-2Kb and thymic leukemia antigen, while similarly with their alpha 3 domains

The murine CD8 glycoprotein interacts with both classical MHC class I molecules and some nonclassical molecules, including the thymic leukemia Ag (TL). TL binds preferentially to CD8alphaalpha homodimers with a 10-fold higher affinity than H-2K(b) class I molecules. To understand the molecular basis for this difference, we created a panel of CD8alpha mutants and tested the ability of the CD8alphaalpha homodimers to bind to H-2K(b) tetramers and TL tetramers. Mutations in three CD8 residues located on the complementarity-determining region-like loops contacting the negatively charged loop in the alpha3 domain of MHC class I greatly reduced binding to both tetramers. Because TL and H-2K(b) class I sequences are highly conserved in the alpha3 domain of MHC class I, this suggests that CD8 contacts the alpha3 domain of TL and H-2K(b) in a similar manner. In contrast, mutations in residues on the A and B beta strands of CD8 that are involved in contact with beta(2)-microglobulin affected interaction with the H-2K(b) tetramer, but not the TL tetramer. Therefore, the orientation of interaction of TL with CD8 appears to be different from that of H-2K(b). The unique high affinity binding of TL with CD8alphaalpha is most likely a result of amino acid differences in the alpha3 domain between TL and H-2K(b), particularly at positions 198 (K to D) and 228 (M to T), which are contact residues in the CD8alphaalpha-H-2K(b) cocrystal.     

Messenger RNA-electroporated dendritic cells presenting MAGE-A3 simultaneously in HLA class I and class II molecules

An optimal anticancer vaccine probably requires the cooperation of both CD4(+) Th cells and CD8(+) CTLs. A promising tool in cancer immunotherapy is, therefore, the genetic modification of dendritic cells (DCs) by introducing the coding region of a tumor Ag, of which the antigenic peptides will be presented in both HLA class I and class II molecules. This can be achieved by linking the tumor Ag to the HLA class II-targeting sequence of an endosomal or lysosomal protein. In this study we compared the efficiency of the targeting signals of invariant chain, lysosome-associated membrane protein-1 (LAMP1) and DC-LAMP. Human DCs were electroporated before or after maturation with mRNA encoding unmodified enhanced green fluorescent protein (eGFP) or eGFP linked to various targeting signals. The lysosomal degradation inhibitor chloroquine was added, and eGFP expression was evaluated at different time points after electroporation. DCs were also electroporated with unmodified MAGE-A3 or MAGE-A3 linked to the targeting signals, and the presentation of MAGE-A3-derived epitopes in the context of HLA class I and class II molecules was investigated. Our data suggest that proteins linked to the different targeting signals are targeted to the lysosomes and are indeed presented in the context of HLA class I and class II molecules, but with different efficiencies. Proteins linked to the LAMP1 or DC-LAMP signal are more efficiently presented than proteins linked to the invariant chain-targeting signal. Furthermore, DCs electroporated after maturation are more efficient in Ag presentation than DCs electroporated before maturation.