Intracellular transport and localization of major histocompatibility complex class II molecules and associated invariant chain

The intracellular transport and location of major histocompatibility complex (MHC) class II molecules and associated invariant chain (Ii) were investigated in a human melanoma cell line. In contrast to the class II molecules, which remain stable for greater than 4 h after synthesis, the associated Ii is proteolytically processed within 2 h. During or shortly after synthesis the NH2-terminal cytoplasmic and membrane-spanning segment is in some of the Ii molecules cleaved off; during intracellular transport, class II associated and membrane integrated Ii is processed from its COOH terminus in distinct steps in endocytic compartments. Immunocytochemical studies at the light and electron microscopic level revealed the presence of class II molecules, but not of Ii on the cell surface. Intracellularly both Ii and class II molecules were localized in three morphologically and kinetically distinct compartments, early endosomes, multivesicular bodies, and prelysosomes. This localization in several distinct endosomal compartments contrasts with the localization of class II molecules in mainly one endocytic compartment in B lymphoblastoid cell lines. As in these lymphoblastoid cell lines Ii is known to be rapidly degraded it is conceivable that the rate of proteolysis of the class II associated Ii and its dissociation from class II molecules modulates the retention of the oligomeric complex in endocytic compartments, and as a consequence the steady-state distribution of these molecules within the endosomal system.     

Efficient endosomal localization of major histocompatibility complex class II-invariant chain complexes requires multimerization of the invariant chain targeting sequence

During biosynthesis, MHC class II-invariant chain complexes are transported into endosomal compartments where invariant chain (Ii) is degraded and class II encounters antigenic peptides. One of the signals that determines this intracellular transport route has been localized to the cytosolic domain of Ii. Deletion of this signal disrupts endosomal targeting and results in the stable expression of class II-Ii complexes at the surface. In this paper we have examined the role of Ii trimerization on the generation of this endosomal localization signal. In L cell transfectants expressing class II and both wild type Ii and a truncated form of Ii that lacks this endosomal localization signal, Ii was found to form multimers which could contain both wild type and truncated Ii. The multimers were not large aggregates but were found to be discrete complexes, probably the nine molecule class II-Ii complex that has been observed in human B cells. The co-expression of truncated Ii allowed for cell surface expression of a subset of wild type Ii. This surface-expressed wild type Ii associated with truncated Ii in multimers at a 2:1 ratio, indicating that these trimers contain two truncated and one wild type Ii molecule. These data suggest a division in trafficking of Ii trimers: if two wild type Ii molecules are present, the complex is transported to and rapidly degraded in endosomes, whereas the presence of only one wild type Ii results in trafficking and expression of the heterotrimer on the cell surface. Following surface arrival, complexes containing only a single wild type Ii molecule are internalized more rapidly and have a shorter half-life than complexes containing only truncated Ii molecules. These data suggest that although a single Ii cytosolic domain can function as a plasma membrane internalization signal, multimerization of Ii is required for efficient Golgi complex to endosome targeting of class II- Ii complexes.     

Isoforms of the invariant chain regulate transport of MHC class II molecules to antigen processing compartments

Newly synthesized class II molecules of the major histocompatibility complex must be transported to endosomal compartments where antigens are processed for presentation to class II-restricted T cells. The invariant chain (Ii), which assembles with newly synthesized class II alpha- and beta-chains in the endoplasmic reticulum, carries one or more targeting signals for transport to endosomal compartments where Ii dissociates from alpha beta Ii complexes. Here we show that the transport route of alpha beta Ii complexes is regulated selectively by two forms of Ii (p33 and p35) that are generated by the use of alternative translation initiation sites. Using a novel quantitative surface arrival assay based on labeling with [6-3H]-D-galactose combined with biochemical modification at the cell surface with neuraminidase, we demonstrate that newly synthesized alpha beta Ii molecules containing the Ii-p33 isoform can be detected on the cell surface shortly after passage through the Golgi apparatus/trans-Golgi network. A substantial amount of these alpha beta Ii complexes are targeted to early endosomes either directly from the trans-Golgi network or after internalization from the cell surface before their delivery to antigen processing compartments. The fraction of alpha beta Ii complexes containing the p35 isoform of Ii with a longer cytosolic domain was not detected at the cell surface as determined by iodination of intact cells and the lack of susceptibility to neuraminidase trimming on ice. However, treatment with neuraminidase at 37 degrees C did reveal that some of the alpha beta Ii-p35 complexes traversed early endosomes. These results demonstrate that a fraction of newly synthesized class II molecules arrive at the cell surface as alpha beta Ii complexes before delivery to antigen processing compartments and that class II alpha beta Ii complexes associated with the two isoforms of Ii are sorted to these compartments by different transport routes.     

How MHC class II molecules reach the endocytic pathway.

We have examined trafficking of major histocompatibility complex (MHC) class II molecules in human B cells exposed to concanamycin B, a highly specific inhibitor of the vacuolar H(+)-ATPases required for acidification of the vacuolar system and for early to late endosomal transport. Neutralization of vacuolar compartments prevents breakdown of the invariant chain (Ii) and blocks conversion of MHC class II molecules to peptide-loaded, SDS-stable alpha beta dimers. Ii remains associated with alpha beta and this complex accumulates internally, as ascertained biochemically and by morphological methods. In concanamycin B-treated cells, a slow increase (> 20-fold) in surface expression of Ii, mostly complexed with alpha beta, is detected. This surface-disposed fraction of alpha beta Ii is nevertheless a minor population that reaches the cell surface directly, or is routed via early endosomes as intermediary stations. In inhibitor-treated cells, the bulk of newly synthesized alpha beta Ii is no longer accessible to fluid phase endocytic markers. It is concluded that the majority of alpha beta Ii is targeted directly from the trans-Golgi network to the compartment for peptide loading, bypassing the cell surface and early endosomes en route to the endocytic pathway.     

Impaired processing and presentation by MHC class II proteins in human diabetic cells

The biochemical processing of and Ag presentation by MHC class II molecules were examined in B cell lines derived from pairs of identical twins discordant for type 1 diabetes. MHC class II defects detected exclusively in cells derived from the twins with autoimmunity included increased rates of transport to and subsequent turnover at the cell surface, inadequate glycosylation, and a reduced display at the cell surface of antigenic peptides. These defects appeared to be secondary to a decreased abundance of the p35 isoform of the invariant chain (Ii), a human-specific chaperone protein for MHC class II normally generated by use of an alternative translation start site. Stable transfection of diabetic B cell lines with an Ii p35 expression vector corrected the defects in MHC class II processing and peptide presentation. A defect in the expression of Ii p35 may thus result in impairment of Ag presentation by MHC class II molecules and thereby contribute to the development of type 1 diabetes in at-risk genotypes.     

Invariant chain protects class II histocompatibility antigens from binding intact polypeptides in the endoplasmic reticulum.

Unlike class I histocompatibility (MHC) antigens, most newly synthesized MHC class II molecules fail to be loaded with peptides in the endoplasmic reticulum (ER), binding instead to the invariant chain glycoprotein (Ii). Ii blocks the class II peptide binding groove until the class II:Ii complexes are transported to endosomes where Ii is removed by proteolysis, thus permitting loading with endosomal short peptides (approximately 12-25 amino acids). Ligands from which the groove is protected by Ii have not yet been identified; theoretically they could be short peptides or longer polypeptides (or both), because the class II groove is open at both ends. Here we show that in Ii- deficient cells, but not in cells expressing large amounts of Ii, a substantial fraction of class II alpha beta dimers forms specific, SDS-resistant 1:1 complexes with a variety of polypeptides. Different sets of polypeptides bound to H-2Ak, Ek, Ed and HLA-DR1 class II molecules; for Ak, a major species of Mr 50 kDa (p50) and further distinct 20 and 130 kDa polypeptides were detectable. Class II binding of p50 was characterized in detail. Point mutations within the Ak antigen binding groove destabilized the p50:class II complexes; a mutation outside the groove had no effect. A short segment of p50 was sufficient for association with Ak. The p50 polypeptide was synthesized endogenously, bound to Ak in a pre-Golgi compartment, and was transported to the cell surface in association with Ak. Thus, Ii protects the class II groove from binding endogenous, possibly misfolded polypeptides in the ER. The possibility is discussed that polypeptide binding is an ancestral function of the MHC antigen binding domain.     

MHC class II-associated invariant chain contains a sorting signal for endosomal compartments

The invariant chain (Ii) is a transmembrane protein that associates with the MHC class II molecules in the endoplasmic reticulum. Expression of Ii in MHC class II-negative CV1 cells showed that it acquired complex-type oligosaccharide side chains and was retained in endosomal compartments. To search for a sorting signal, we made progressive deletions from the cytoplasmic N-terminus of Ii. Deleting 11 amino acid residues resulted in a protein that was still sorted and retained in endosomal vesicles, whereas deletion of 15 or more amino acid residues resulted in a protein that became resident in the plasma membrane. Amino acids 12-15 are thus essential for intracellular transport to endosomal compartments. As Ii is intracellularly associated with the MHC class II molecules, it is proposed that Ii determines the intracellular transport route of these molecules.     

Functional early endosomes are required for maturation of major histocompatibility complex class II molecules in human B lymphoblastoid cells.

Major histocompatibility complex (MHC) class II molecules are targeted together with their invariant chain (Ii) chaperone from the secretory pathway to the endocytic pathway. Within the endosome/lysosome system, Ii must be degraded to enable peptide capture by MHC class II molecules. It remains controversial exactly which route or routes MHC class II/Ii complexes take to reach the sites of Ii processing and peptide loading. We have asked whether early endosomes are required for successful maturation of MHC class II molecules by using an in situ peroxidase/diaminobenzidine compartment ablation technique. Cells whose early endosomes were selectively ablated using transferrin-horseradish peroxidase conjugates fail to mature their newly synthesized MHC class II molecules. We show that whereas transport of secretory Ig through the secretory pathway is virtually normal in the ablated cells, newly synthesized MHC class II/Ii complexes never reach compartments capable of processing Ii. These results strongly suggest that the transport of the bulk of newly synthesized MHC class II molecules through early endosomes is obligatory and that direct input into later endosomes/lysosomes does not take place.     

Murine class II (Ia) molecules associate with human invariant chain

Polymorphic class II (Ia) major histocompatibility complex (MHC) gene products associate intracytoplasmically with a third nonpolymorphic class II molecule, the invariant chain (Ii), which is encoded by gene(s) unlinked to the MHC. Although the role of the Ii chain in the expression of cell surface Ia molecules is unclear, it has been suggested that the Ii chain helps in the assembly and intracellular transport of class II antigens. In this study, we demonstrate that the murine polymorphic class II antigens of an interspecies mouse-human hybrid, which has segregated the murine invariant chain gene, associates with the human invariant chain gene intracytoplasmically. The murine Ia antigens are expressed on the cell surface and can function as restriction elements in antigen presentation to T cells. The biochemical analysis demonstrates that the regions of the Ii gene that are critical to its interaction with Ia molecules are conserved between species.     

Formation of complexes between self-peptides and MHC class II molecules in cells defective for presentation of exogenous protein antigens.

A vertebrate immune response is initiated by the presentation of foreign protein Ag to MHC class II-restricted T lymphocytes by specialized APC. Presentation of self-peptides in association with MHC class II molecules is also necessary for the induction of T cell tolerance. It is important to understand whether functionally divergent APC are responsible for delivering these distinct signals to class II-restricted T cells. Here we examine the ability of I-Ad surface molecules expressed in diverse cell types to stimulate I-Ad-restricted T cells. Recipients included J558L myeloma cells and EL4 lymphoma cells expressing barely detectable or undetectable levels of Ii chain mRNA. This allowed us to examine the influence of Ii expression on the presentation of intracellular Ag and thus test the hypothesis that Ii chain is necessary to prevent access of self-peptides to newly synthesized class II molecules. Ii chain expression did not restore the ability of transformants to process and present soluble protein Ag. A striking result was the finding that cells showing a defect in the exogenous class II presentation pathway were capable of functioning as stimulators when they expressed intracellular secreted but not signal-less V-CH3b Ag. Thus, so-called professional APC that can capture and process exogenous protein Ag may express a specialized set of proteins not required for the presentation of self-peptides.     

Stable surface expression of invariant chain prevents peptide presentation by HLA-DR.

Class II major histocompatibility complex (MHC) molecules are cell surface glycoproteins that bind and present immunogenic peptides to T cells. Intracellularly, class II molecules associate with a polypeptide referred to as the invariant (Ii) chain. Ii is proteolytically degraded and dissociates from the class II complex prior to cell surface expression of the mature class II alpha beta heterodimer. Using human fibroblasts transfected with HLA-DR1 and Ii cDNAs, we now demonstrate that truncation of the cytoplasmic domain of Ii results in the failure of Ii to dissociate from the alpha beta Ii complex and leads to stable expression of class II alpha beta Ii complexes on the cell surface. Furthermore, biochemical analysis and peptide presentation assays demonstrated that transfectants with stable surface alpha beta Ii complexes expressed very few free alpha beta heterodimers at the surface and were very inefficient in their ability to present immunogenic peptides to T cells. These results support the hypothesis that the cytoplasmic domain of Ii is responsible for endosomal targeting of alpha beta Ii and directly demonstrate that association with Ii interferes with the antigen presentation function of class II molecules.     

Invariant chain and the MHC class II cytoplasmic domains regulate localization of MHC class II molecules to lipid rafts in tumor cell-based vaccines

Cell-based tumor vaccines, consisting of MHC class I+ tumor cells engineered to express MHC class II molecules, stimulate tumor-specific CD4+ T cells to mediate rejection of established, poorly immunogenic tumors. Previous experiments have demonstrated that these vaccines induce immunity by functioning as APCs for endogenously synthesized, tumor-encoded Ags. However, coexpression of the MHC class II accessory molecule invariant chain (Ii), or deletion of the MHC class II cytoplasmic domain abrogates vaccine immunogenicity. Recent reports have highlighted the role of lipid microdomains in Ag presentation. To determine whether Ii expression and/or truncation of MHC class II molecules impact vaccine efficacy by altering MHC class II localization to lipid microdomains, we examined the lipid raft affinity of MHC class II molecules in mouse M12.C3 B cell lymphomas and SaI/A(k) sarcoma vaccine cells. Functional MHC class II heterodimers were detected in lipid rafts of both cell types. Interestingly, expression of Ii in M12.C3 cells or SaI/A(k) cells blocked the MHC class II interactions with cell surface lipid rafts. In both cell types, truncation of either the alpha- or beta-chain decreased the affinity of class II molecules for lipid rafts. Simultaneous deletion of both cytoplasmic domains further reduced localization of class II molecules to lipid rafts. Collectively, these data suggest that coexpression of Ii or deletion of the cytoplasmic domains of MHC class II molecules may reduce vaccine efficacy by blocking the constitutive association of MHC class II molecules with plasma membrane lipid rafts.     

Mouse B lymphocyte specific endocytosis and recycling of MHC class II molecules

In B lymphocytes, the processing of exogenous proteins and the subsequent binding of antigenic peptides to class II molecules encoded by the major histocompatibility complex (MHC) occurs most likely within endocytic compartments. To examine the endocytic transport of MHC class II molecules, we used (i) surface iodination followed by internalization, pronase treatment and immunoprecipitation, (ii) in situ iodination of endosomal compartments, and (iii) confocal microscopy to visualize the fate of fluorescence coupled Fab fragments. In murine I-Ak, I-Ek positive B lymphoma cells, cell surface MHC class II molecules are partially protected from pronase digestion after 15 min at 37 degrees C and recycled back to the cell surface within the next 30 min. The fluorescence coupled Fab fragments are delivered to juxtanuclear endocytic compartments in 15 min. In contrast to the murine B cells, L fibroblasts transfected with either I-A alpha beta k or I-E alpha k beta k,d fail to internalize their surface class II molecules. A fraction of class II molecules, however, is still present in endosomal compartments as detected after in situ iodination in L fibroblasts. We conclude that the recipient L fibroblasts lack one or several factors needed for the transport of MHC class II molecules from the cell surface to the endosomes. We suggest that in murine B lymphoma cells, antigenic peptides can gain access to a pool of recycling class II molecules whereas in L cells they meet newly synthesized class II molecules targeted to the endosomal compartments.     

BALB/c invariant chain mutant mice display relatively efficient maturation of CD4+ T cells in the periphery and secondary proliferative responses elicited upon peptide challenge.

Allelic differences are known to influence many important aspects of class II biosynthesis, including subunit assembly, Ii chain associations, and DM-mediated peptide loading. Mutant mouse strains lacking Ii chain expression have been previously studied on mixed genetic backgrounds. The present experiments describe cellular and functional characteristics of congenic BALB/c Ii chain mutants. As expected, class II surface expression was markedly decreased, but in contrast to I-Ad-transfected cell lines, serological analysis of BALB/c Ii chain-deficient spleen cells gave no evidence for discordant expression of class II conformational epitopes. Thus, we conclude that properly folded class II molecules are exported via the Ii chain-independent pathway. Functional assays demonstrate consistently superior peptide-loading capabilities, suggesting that these I-Ad molecules are empty or occupied by an easily displaced peptide(s). Defective B cell development was observed for three mutant strains established on diverse genetic backgrounds. Ii chain function is also essential for optimal class II surface expression by mature splenic dendritic cells. Surprisingly, we observe in BALB/c Ii chain mutants, relatively efficient maturation of CD4+ T cells in the periphery and secondary proliferative responses elicited upon peptide challenge. The milder phenotype displayed by BALB/c Ii chain mutants in comparison with class II functional defects previously described for mouse strains lacking Ii chain is likely to have an effect on disease susceptibility.     

Transient surface delivery of invariant chain-MHC II complexes via endosomes: a quantitative study

Newly synthesized major histocompatibility complex class II needs to be directed to late endocytic compartments to combine with peptide antigens. Efficient transport requires complexes of major histocompatibility complex class II and invariant chain (αβIi). Since such complexes have been detected on the plasma membrane in human cells, this compartment was proposed as the primary destination for αβIi exiting the trans-Golgi network. Here, I have used density gradient electrophoresis and selective biotinylation to investigate the trafficking route of αβIi quantitatively. Density gradient electrophoresis analysis showed that αβIi was transported from the trans-Golgi network to endosomes at ∼ 1.7% min⁻¹. Surface delivery of αβIi was delayed relative to endosome transport by ∼ 10 min and showed slower kinetics (∼ 0.4% min⁻¹), suggesting that αβIi reached the plasma membrane only after arrival in endosomes. A biotinylation assay revealed that 20–40% of endosomal αβIi was delivered to the plasma membrane at steady state, suggesting that surface αβIi was entirely derived from endosomes. Surface αβIi was rapidly re-internalized and either returned to the cell surface or accessed degradative compartments. Peptide loading commenced ∼ 30 min after delivery to endosomes. Thus αβIi directly traffics from trans-Golgi network to endosomes and enters an endosome–plasma membrane 'carousel' until transport to peptide-loading compartments ensues .     

Mycobacterium bovis BCG attenuates surface expression of mature class II molecules through IL-10-dependent inhibition of cathepsin S

We have previously shown that macrophage infection with Mycobacterium tuberculosis and M. bovis bacillus Calmette-Guérin (BCG) partially inhibits MHC class II surface expression in response to IFN-gamma. The present study examined the nature of class II molecules that do in fact reach the surface of infected cells. Immunostaining with specific Abs that discriminate between mature and immature class II populations showed a predominance of invariant chain (Ii)-associated class II molecules at the surface of BCG-infected cells suggesting that mycobacteria specifically block the surface export of peptide-loaded class II molecules. This phenotype was due to inhibition of IFN-gamma-induced cathepsin S (Cat S) expression in infected cells and the subsequent intracellular accumulation of alphabeta class II dimers associated with the Cat S substrate Ii p10 fragment. In contrast, infection with BCG was shown to induce secretion of IL-10, and addition of blocking anti-IL-10 Abs to cell cultures restored both expression of active Cat S and export of mature class II molecules to the surface of infected cells. Consistent with these findings, expression of mature class II molecules was also restored in cells infected with BCG and transfected with active recombinant Cat S. Thus, M. bovis BCG exploits IL-10 induction to inhibit Cat S-dependent processing of Ii in human macrophages. This effect results in inhibition of peptide loading of class II molecules and in reduced presentation of mycobacterial peptides to CD4(+) T cells. This ability may represent an effective mycobacterial strategy for eluding immune surveillance and persisting in the host.     

MHC class II molecules on the move for successful antigen presentation

Major histocompatibility complex class II (MHC II) molecules are targeted to endocytic compartments, known as MIIC, by the invariant chain (Ii) that is degraded upon arrival in these compartments. MHC II acquire antigenic fragments from endocytosed proteins for presentation at the cell surface. In a unique and complex series of reactions, MHC II succeed in exchanging a remaining fragment of Ii for other protein fragments in subdomains of MIIC before transport to the cell surface. Here, the mechanisms regulating loading and intracellular trafficking of MHC II are discussed.     

Cathepsin S controls the trafficking and maturation of MHC class II molecules in dendritic cells

Before a class II molecule can be loaded with antigenic material and reach the surface to engage CD4+ T cells, its chaperone, the class II-associated invariant chain (Ii), is degraded in a stepwise fashion by proteases in endocytic compartments. We have dissected the role of cathepsin S (CatS) in the trafficking and maturation of class II molecules by combining the use of dendritic cells (DC) from CatS(-/-) mice with a new active site-directed probe for direct visualization of active CatS. Our data demonstrate that CatS is active along the entire endocytic route, and that cleavage of the lysosomal sorting signal of Ii by CatS can occur there in mature DC. Genetic disruption of CatS dramatically reduces the flow of class II molecules to the cell surface. In CatS(-/-) DC, the bulk of major histocompatibility complex (MHC) class II molecules is retained in late endocytic compartments, although paradoxically, surface expression of class II is largely unaffected. The greatly diminished but continuous flow of class II molecules to the cell surface, in conjunction with their long half-life, can account for the latter observation. We conclude that in DC, CatS is a major determinant in the regulation of intracellular trafficking of MHC class II molecules.     

Polarized expression of CD74 by gastric epithelial cells.

CD74 is known as the major histocompatibility complex (MHC) class II-associated invariant chain (Ii) that regulates the cell biology and functions of MHC class II molecules. Class II MHC and Ii expression was believed to be restricted to classical antigen-presenting cells (APC); however, during inflammation, other cell types, including mucosal epithelial cells, have also been reported to express class II MHC molecules. Given the importance of Ii in the biology of class II MHC, we sought to examine the expression of Ii by gastric epithelial cells (GEC) to determine whether class II MHC molecules in these nonconventional APC cells were under the control of Ii and to further support the role that these cells may play in local immune and inflammatory responses during Helicobacter pylori infection. Thus we examined the expression of Ii on GEC from human biopsy samples and then confirmed this observation using independent methods on several GEC lines. The mRNA for Ii was detected by RT-PCR, and the various protein isoforms were also detected. Interestingly, these cells have a high level expression of surface Ii, which is polarized to the apical surface. These studies are the first to demonstrate the constitutive expression of Ii by human GEC.     

Expression of invariant chain can cause an allele-dependent increase in the surface expression of MHC class I molecules

Invariant chain (Ii) has been shown to play a significant part in the assembly of MHC class II molecules. Ii also binds to MHC class I, although it is not known when this first occurs or whether it can affect class I assembly. Our examination of lysates of L(d)-transfected T2 cells showed that Ii bound intracellularly to folded, but not to open, forms of MHC class I. Furthermore, addition of peptides to the lysates dissociated Ii from the Ii-folded MHC class I complex. Thus, unlike other known chaperones, Ii associates only with folded, peptide-free class I molecules. To determine whether Ii can affect MHC class I transport and surface expression, we used both wild-type Ii and a mutant Ii that lacked the endosomal targeting sequence. Neither Ii nor Ii(Delta 20) increased the rate of MHC class I migration; however, Ii and (to a greater extent) Ii(Delta 20) increased cell surface expression of MHC class I. In HeLa cells, this effect was allele-specific, affecting HLA-A28 more than -B75. Ii also increased the surface expression of K(b) more than D(b) on Panc02 pancreatic adenocarcinoma cells. Neither form of Ii was detectable at the cell surface with MHC class I, indicating that Ii had exercised its effect on class I intracellularly. In total, these data suggest that Ii can bind peptide-free folded class I/beta(2)m heterodimers, but not open MHC class I heavy chains, in the endoplasmic reticulum, and that Ii can facilitate the surface expression of the MHC class I molecule.