Intracellular transport of class I histocompatibility molecules. Influence of protein folding on transport to the cell surface

Structural analysis of H2-Db class I molecules containing two different allelic forms of the type 1 diabetes susceptibility factor beta-2 microglobulin: Implications for the mechanism underlying variations in antigen presentation

Beta-2 microglobulin (beta2m) is a member of the immunoglobulin-like domain superfamily that is an essential structural subunit of the MHC class I (MHC-I) molecule. beta2m was previously identified as a susceptibility factor for the development of type 1 diabetes (T1D) in NOD mice, whereby transgenic expression of the beta2ma variant, but not the beta2mb variant, restored diabetes susceptibility to normally resistant NOD.beta2mnull mice. Here we report the crystal structures and thermodynamic stabilities of the NOD MHC-I molecule H2-Db containing these two variants. Our results reveal subtle differences in the structures of the beta2m variants, namely in minor loop shifts and in variations in the hydrogen bonding networks at the interfaces between the components of the ternary complex. We also demonstrate that the thermodynamic stabilities of the beta2m variants in isolation differ. However, the conformation of the peptide in the MHC cleft is unchanged in beta2m allelic Db complexes, as are the TCR recognition surfaces. Thus, despite modest structural differences between allelic complexes, the evidence indicates that Db peptide presentation of the representative peptide is unchanged in the context of either beta2m allelic variant. These data suggest that other mechanisms, such as differential association of MHC-I in multiprotein complexes, are likely responsible for the effect of beta2m on T1D development.

The protein-tyrosine phosphatase CD45 reaches the cell surface via golgi-dependent and -independent pathways

CD45 is a receptor protein-tyrosine phosphatase essential for T cell development and lymphocyte activation. It is highly glycosylated, with multiple isoforms and glycoforms expressed on the cell surface depending on the cell type and stage of differentiation. Interestingly, we found two pools of newly synthesized CD45 expressed on plasma membrane, one of which arrived by 5 min after synthesis. The remaining pool of CD45 was fully glycosylated and began to arrive at the cell surface at approximately 15 min. The rapidly expressed population of CD45 possessed exclusively endoglycosidase H-sensitive N-linked carbohydrate. Additionally, this rapidly expressed pool of CD45 appeared on the cell surface in a brefeldin A (BFA)-insensitive manner, suggesting that it reached the cell surface independent of the Golgi complex. The remaining CD45 trafficked through the Golgi complex, and transport proceeded via a BFA-sensitive mechanism. These data suggest that CD45 is able to reach the cell surface via two distinct routes. The first is a conventional Golgi-dependent pathway that allows fully processed CD45 to be expressed. The second utilizes an ill defined mechanism that is independent of the Golgi, is BFA-resistant, and allows for the expression of CD45 with immature carbohydrate on the cell surface.

Selective export of MHC class I molecules from the ER after their dissociation from TAP

It has been assumed that upon dissociation from TAP, MHC class I molecules exit the ER by nonselective bulk flow. We now show that exit must occur by association with cargo receptors. Inconsistent with exit by bulk flow, loading of MHC class I molecules with high-affinity peptides triggers dissociation from TAP but has no effect on rates of ER-to-Golgi transport. Moreover, peptide-loaded MHC class I molecules accumulate at ER exit sites from which TAP molecules are excluded. Consistent with receptor-mediated exit, ER-to-Golgi transport of MHC class I molecules is independent of their cytoplasmic tails, which themselves lack ER export motifs. In addition, we show that MHC class I molecules associate with the putative cargo receptor BAP31.

Accelerated secretion of mutant beta-lactoglobulin in Saccharomyces cerevisiae resulting from a single amino acid substitution

Transformed yeasts producing a mutant form of bovine beta-lactoglobulin (beta-LG), W19Y, in which Trp(19) was replaced with Tyr, were shown to secrete 6 times more than those producing wild type beta-LG. Northern blot analysis suggested that the enhanced level of secretion was not the result of upregulated transcription of W19Y. The ratio of the amount of W19Y secreted into the supernatant to the amount of W19Y remaining inside the cells was much larger than that in the case of wild type beta-LG as shown by immunoblot analysis. A pulse/chase experiment revealed that the speed of secretion of W19Y was significantly accelerated, compared to wild type beta-LG. These results indicated that W19Y was more efficiently and rapidly transported in the course of secretion than wild type beta-LG. Our previous study showed that the DeltaG of unfolding of W19Y in water is 6.9 kcal/mol smaller than that of wild type beta-LG. Furthermore, immunoblot analysis of intracellular beta-LG under non-reducing conditions indicated that W19Y as well as wild type beta-LG maintained a specific folded structure inside the yeast cells, whereas other non-secretable mutant beta-LGs with Phe or Ala at position 19 (W19F and W19A, respectively) did not. These data suggest that low molecular stability and the maintenance of a specific folded structure inside the yeast cells are prerequisites for efficient and rapid secretion. W19Y was more efficiently secreted than wild type beta-LG also in transformed ern1 mutant yeast cells expressing only a basal level of BiP which is considered to function in quality control in the endoplasmic reticulum (ER) by playing an important role in determining the secretion efficiency of secretory proteins. Thus, the reason for the enhanced secretion of W19Y is considered to be that the improved folding ability of W19Y can allow the half-life of the W19Y-BiP complex to become shorter than that of the wild type beta-LG-BiP complex, leading to faster translocation of W19Y into transport vesicles, or that W19Y can fold in a BiP-independent manner in the ER of the yeast cells. Our findings demonstrate that the amount of protein secreted can be improved by alteration of a single amino acid residue crucial for its structure.

Db-binding peptides from influenza virus: effect of non-anchor residues on stability and immunodominance

Relative affinities were determined for the interaction of H-2Db with all the peptides from the A/PR/8/34 strain of influenza virus that contained the Db-binding motif. The results indicated that, even though 23 peptides with the appropriate motif were identified and analysed, binding of only five of them could be detected at peptide concentrations lower than 10(-7) M. Of these five, only one, TGICNQNII, bound with better affinity than the nucleoprotein-derived natural epitope, ASNENMETM. The origin of the higher binding peptide was the influenza neuraminidase, a protein for which little cytosolic processing would be expected since it is a surface glycoprotein. To establish why many of the influenza-derived peptides did not bind, the role of non-anchor residues on Db-peptide interactions was analysed, using a scheme where QDIENEEKI, a non-binding peptide from the influenza virus polymerase 1, was sequentially converted to ASNENMETI, which binds to Db with an affinity similar to that of ASNENMETM. Although all positions examined influenced peptide binding, peptide residue no. 2 (P2) was of particular importance. Therefore, each of the 20 naturally occurring amino acids were inserted at this position to investigate their effects on peptide-MHC interaction. The results indicated that amino acids having side chains with charged or ring structures were deleterious, while non-polar and polar residues were either neutral or facilitated binding to different degrees. Our data also indicated that every residue of the peptide contributes to the stability of the MHC-peptide complex, and the final affinity is dependent on the nature of the amino acids at each position, not just on those at a small number of anchor positions. The results also suggested that increased stability, as indicated by the half-life of the peptide-MHC class I complex, might play an important role in selecting the immunodominant epitope.

Presentation of an exogenous antigen by major histocompatibility complex class I molecules

Cytotoxic T lymphocytes (CTL) generally recognize peptides derived from endogenously expressed proteins in association with nascent major histocompatibility complex (MHC) class I molecules. In contrast, peptides derived from exogenous proteins associate with MHC class II following endocytosis to an endosomal compartment. However, we have recently demonstrated that exogenous fusion proteins consisting of the binding and translocating domains of Pseudomonas exotoxin (PE) fused with CTL epitopes derived from either influenza matrix protein (PEMa) or nucleoprotein are internalized, processed, targeted to and presented by MHC class I (Donnelly et al. 1993, Proc. Natl. Acad. Sci. USA 1993. 90: 3530). PE is known to be internalized, processed in endosomes, and translocated to the cytosol during intoxication of cells. However, our present studies demonstrate that, unlike PE, PEMa does not require translocation to the cytosol to exert its effect. First, two inhibitors of PE toxicity that exert their effects at steps subsequent to endosomal processing had no effect on the sensitization of target cells for CTL-mediated lysis by PEMa. NH4Cl, which inhibits PE by raising endosomal pH, and brefeldin A, which inhibits PE by disrupting the Golgi complex, did not inhibit sensitization of targets cells by PEMa. Second, PEMa was capable of sensitizing for lysis T2 mutant cells, which are defective in transport of peptides from the cytosol to the lumen of the endoplasmic reticulum for presentation by MHC class I. These results suggest that PEMa is proteolytically processed in endosomes, and association with MHC class I does not require nascent MHC molecules. Such a process may involve internalized MHC class I, and subsequent expression of the peptide-MHC complexes on the cell surface would then lead to recognition by CTL.

A single amino acid substitution in the H-2Kb molecule generates a defined allogeneic epitope

Using Mitomycin C mutagenesis and negative and positive selection with monoclonal antibodies specific for H-2Kb and H-2Kbm10, respectively, a mutant cell line clone, Mitc-182, was isolated. Direct sequencing of uncloned cDNA as well as PCR based cloning and sequencing of the H-2Kb182 transcript from this mutant revealed a single G-->T transversion resulting in the substitution of Trp167 by cysteine. Serologically, the mutant Kb182 and Kbm10 are almost identical as each has lost at least five Kb specific mAb epitopes and gained several new epitopes. Interestingly, the mutant cell line, Mitc-182, is efficiently recognized by alloreactive CTLs raised in reciprocal combinations, e.g. CB6 anti Cbm10 and Cbm10 anti CB6, indicating that Kb182 contains both Kb and Kbm10 specific epitopes. The mutation has not affected the ability of Kb182 to present Kb restricted antigenic peptides of Sendai and vesicular stomatitis viruses. In addition to underscoring the importance of amino acid residue 167 in alloreactivity, these results indicate a positive correlation between the gain of both an mAb epitope and a defined alloreactive CTL epitope.

Unique biochemical properties of a mutant MHC class I molecule, H-2Ksm1

This study describes serological and biochemical properties of a novel MHC class I molecule. The mutant H-2Ksm1 molecule was discovered in a mouse because of loss of reactivity of its peripheral blood lymphocytes to monoclonal antibodies. This mutation in the H-2Ks molecule is the first in vivo mutation described that has altered an amino acid residue (amino acid 107) distant from the regions generally considered to be peptide or TCR contacts. Cell surface expression of the mutant molecules remains high but the Arg107 to Trp substitution appears to alter the native protein conformation, markedly decreasing cell surface association with beta 2-microglobulin light chains and conferring a loss of recognition by Ks specific antibodies.

Mapping the orientation of an antigenic peptide bound in the antigen binding groove of H-2Kb using a monoclonal antibody

The major histocompatibility complex class I molecules are receptors for intracellular peptides, both of self and non-self origin. When non-self peptides (eg., pathogen derived) are bound to the class I molecules, they form ligands for T cell receptors resulting in antigen specific lysis of the infected cells by cytotoxic T lymphocytes. Therefore, an understanding of the process of antigen recognition requires the precise definition of the structural features of the bimolecular complex formed by a single well defined antigenic peptide bound to the class I molecule. A strategy using antibodies was developed to probe the structural features of the H-2Kb containing a defined peptide in the antigen cleft. We report that the binding surface area of a Kb specific monoclonal antibody (28-13-3s) includes residues in the alpha 1 (Gly56 and Glu58) and alpha 2 (Trp167) helices of Kb thus, binding across the antigen binding groove. When cells treated with the antigenic peptide of vesicular stomatitis virus, N52-59, and its alanine substituted analogs were tested for 28-13-3s binding, it was found that position 1 of the peptide also forms a part of the antibody binding site. This finding strongly supports the positioning of the N-terminus of N52-59 proximal to pocket A, thus, assuming an orientation parallel to the alpha 1 helix.

Expression of the wild-type and mutated vacuolar storage protein phaseolin in Xenopus oocytes reveals relationships between assembly and intracellular transport

The role played by subunit assembly in the intracellular transport of the bean storage protein phaseolin, a soluble trimeric glycoprotein, was investigated using Xenopus oocytes injected with RNA. We show that phaseolin assembly is dependent upon the level of synthesis of the protein and is required for intracellular transport out of the endoplasmic reticulum. We also show that a fraction of the assembled phaseolin is permanently retained in a post-endoplasmic reticulum compartment. Deletion of the C-terminal alpha-helical domain fully prevents in vivo assembly but not endoplasmic reticulum retention. This indicates that this domain is necessary for trimerization but not for interactions of unassembled subunits with endoplasmic reticulum components. The truncated phaseolin has high in vivo stability. The potential implications of these findings on the possibility to improve the nutritional value of phaseolin through genetic engineering are discussed.

Role of de novo protein synthesis in target cells recognized by cytotoxic T lymphocytes specific for vesicular stomatitis virus

The requirements for viral and host protein synthesis in the generation of target antigens for cytotoxic T lymphocytes (CTL) was evaluated by using vesicular stomatitis virus (VSV) inactivated by UV irradiation (UV-VSV). EL4 target cells incubated with UV-VSV were recognized and lysed by anti-VSV CTL, indicating that de novo synthesis of viral proteins was not required for the generation of antigens recognized by antiviral CTL. Anti-VSV CTL from H-2b mice primarily recognize determinants derived from the VSV N protein bound to the class I major histocompatibility complex (MHC) antigen H-2Kb. Comparison of a cloned CTL line representing this specificity and a heterogeneous population of anti-VSV CTL showed that determinants other than that recognized by the cloned CTL were generated more efficiently from UV-VSV. By using vaccinia virus recombinants that express deletion fragments of the N protein, it was shown that these additional determinants were probably derived from VSV proteins other than the N protein. The protein synthesis inhibitor emetine was used to determine whether newly synthesized host proteins were required for antigen generation. The addition of emetine to target cells prior to or at the time of the addition of UV-VSV inhibited lysis by anti-VSV CTL. This inhibition could be due to depletion of newly synthesized MHC molecules from intracellular membranes. This hypothesis was supported by using brefeldin A to delay membrane protein transport in target cells during the time of incubation with emetine and UV-VSV, which resulted in partial reversal of the effect of emetine. These results suggest that newly synthesized class I MHC molecules are required for the generation of antigens recognized by anti-VSV CTL.

Behavior of cysteine mutants of human lysozyme in de novo synthesis and in vivo secretion

To investigate the mechanism of disulfide-bond-coupled de novo folding of human lysozyme, we have constructed 23 mutant enzymes in which cysteine residue(s) were replaced by alanine(s). The mutant genes were translated in vitro in a system composed of rabbit reticulocyte lysate, canine pancreatic microsomal vesicles and oxidized glutathione. This system allows the formation of intramolecular disulfide bonds in translation products translocated into the microsomal lumen. The mobilities of the translation products were analyzed by SDS/PAGE in nonreducing conditions. Some mutant lysozymes were found to form a compact conformation with native-like mobility in the presence of SDS. The de novo formation of the SDS-resistant compact conformation of each mutant correlated well with its efficiency of secretion by Saccharomyces cerevisiae. Our results suggest that the de novo synthesized products reflect the conformational states in vivo to some extent, and that the formation of SDS-resistant compact conformation can be regarded as a necessary condition for allowing lysozyme to be secreted. In addition, the analysis of a mutant C116A (Cys116----Ala) under different oxidative conditions suggests two distinct pathways for the disulfide-bond-coupled formation of the compact conformation.

Molecular analysis of H-2 class I molecules expressed on the UV-induced tumour 1591

We have biochemically characterized by 2D (two-dimensional) electrophoresis three novel class I molecules called A166, A149 and A216 expressed by 1591, a UV-induced fibrosarcoma, and have compared them to class I molecules expressed by mice of the H-2q and H-2s haplotypes. A166 and A149 are very similar if not identical to Dq and Lq respectively. We have shown, using HPLC (high-pressure liquid chromatography) tryptic peptide mapping, that the expression of A166 is approximately three fold greater than A149, reminiscent of Dd compared to Ld. In addition A216 possess an identical isoelectric point to that of the Ks molecule. We demonstrate that outbred Swiss Webster mice express an analogous constellation of class I molecules and we conclude that our results can be most easily interpreted in terms of an allogeneic origin for the novel class I molecules expressed on 1591.

Different class I antigen oligosaccharides on a murine tumor and a lectin-resistant variant are not responsible for the differential recognition of the tumors by CTL

Previous studies have shown that whereas a highly malignant mouse cell line termed MDAY-D2 (d haplotype) does not elicit a detectable response by cytotoxic T lymphocytes (CTL) in DBA/2 mice, strong anti-tumor CTL are generated against a wheat-germ-agglutinin-resistant variant, designated MDW3. Additional evidence suggests these anti-MDW3 CTL may not be a consequence of a unique antigenic determinant on the variant cells. Because MDW3 cells are expected to differ from MDAY-D2 cells in their surface carbohydrate structures (due to their lectin resistance) and Class I major histocompatibility molecules play a crucial role in CTL-mediated responses, we speculated that the Asn-linked oligosaccharides present on Class I molecules of MDAY-D2 and MDW3 might be different and could potentially influence recognition analyses and Con A-Sepharose affinity chromatography clearly demonstrated that the oligosaccharides isolated from the H-2Dd molecule of MDAY-D2 cells are larger and more highly branched than those of the MDW3 variant. Taken together with the finding that anti-MDW3 CTL are restricted by H-2Dd, these results suggested that the larger H-2Dd oligosaccharides on MDAY-D2 cells could potentially mask or perturb determinants required for recognition by these CTL. To test this postulate, the surface Class I oligosaccharides of both MDAY-D2 and MDW3 cells were converted to simpler hybrid structures by treatment with the oligosaccharide processing inhibitor, swainsonine. However, no effect was observed on the lysis or binding of either MDAY-D2 or MDW3 cells by anti-MDW3 CTL. Thus, the results do not support the possibility that the larger H-2Dd oligosaccharides on MDAY-D2 cells are, in themselves, responsible for the poor recognition of the parent tumor by anti-MDW3 CTL. Our data do indicate, however, that CTL target binding and effector functions are not dependent on the fine structure of complex Asn-linked carbohydrates present on Class I molecules and possibly on other, accessory molecules at the target cell surface, since MDW3 cells maintained their sensitivity to lysis by CTL following swainsonine treatment.