Mixed isotype class II antigen expression. A novel class II molecule is expressed on a murine B cell lymphoma

Assembly, Intracellular Transport, and Release of MHC Class II Peptide Receptors

MHC class II molecules play a pivotal role for the induction and maintenance of immune responses against pathogens, but are also implicated in pathological conditions like autoimmune diseases or rejection of transplanted organs. Human antigen-presenting cells express three human leukocyte antigen (HLA) class II isotypes (DR, DP, and DQ), which are, with the exception of DRα, composed of highly polymorphic α and β subunits. The combination of α- and β-chains results in a multitude of MHC-II αβ-heterodimers of the same isotype, but also isotype-mixed MHC class II molecules have been identified. Invariant chain chaperones the assembly of MHC-II molecules within the endoplasmatic reticulum and also facilitates the intracellular transport to MHC class II loading compartments (MIICs). MHC-II molecules are loaded with antigenic peptides and shuttled to the cell surface for inspection by CD4 T-cells. Alternatively, class-II molecules enriched on intraluminal vesicles can be released via exosomes into the extracellular space. Since some of the αβ-combinations may yield mismatched nonfunctional heterodimers, it is not entirely clear which type of HLA class II peptide receptors are transported to MIICs and found on the cell surface of antigen-presenting cells. We present techniques to inspect assembly, intracellular transport, cell surface expression, and exosomal release of MHC class II heterodimers.

Bone marrow laminins influence hematopoietic stem and progenitor cell cycling and homing to the bone marrow

Hematopoietic stem and progenitor cell (HSPC) functions are regulated by a specialized microenvironment in the bone marrow - the hematopoietic stem cell niche - of which the extracellular matrix (ECM) is an integral component. We describe here the localization of ECM molecules, in particular the laminin α4, α3 and α5 containing isoforms in the bone marrow. Laminin 421 (composed of laminin α4, β2, γ1 chains) is identified as a major component of the bone marrow ECM, occurring abundantly surrounding venous sinuses and in a specialized reticular fiber network of the intersinusoidal spaces of murine bone marrow (BM) in close association with HSPC. Bone marrow from Lama4^-/- mice is significantly less efficient in reconstituting the hematopoietic system of irradiated wildtype (WT) recipients in competitive bone marrow transplantation assays and shows reduced colony formation in vitro. This is partially due to retention of Lin^-c-kit⁺Sca-1⁺CD48^- long-term and short-term hematopoietic stem cells (LT-HSC/ST-HSC) in the G0 phase of the cell cycle in Lama4^-/- bone marrow and hence a more quiescent phenotype. In addition, the extravasation of WT BM cells into Lama4^-/- bone marrow is impaired, influencing the recirculation of HSPC. Our data suggest that these effects are mediated by a compensatory expression of laminin α5 containing isoforms (laminin 521/522) in Lama4^-/- bone marrow. Collectively, these intrinsic and extrinsic effects lead to reduced HSPC numbers in Lama4^-/- bone marrow and reduced hematopoietic potential.

A novel family of human leukocyte antigen class II receptors may have its origin in archaic human species

HLA class II α and β chains form receptors for antigen presentation to CD4(+) T cells. Numerous pairings of class II α and β subunits from the wide range of haplotypes and isotypes may form, but most of these combinations, in particular those produced by isotype mixing, yielded mismatched dimers. It is unclear how selection of functional receptors is achieved. At the atomic level, it is not known which interactions of class II residues regulate selection of matched αβ heterodimers and the evolutionary origin of matched isotype mixed dimer formation. In this study we investigated assembly of isotype-mixed HLA class II α and β heterodimers. Assembly and carbohydrate maturation of various HLA-class II isotype-mixed α and β subunits was dependent on the groove binding section of the invariant chain (Ii). By mutation of polymorphic DPβ sequences, we identified two motifs, Lys-69 and GGPM-(84-87), that are engaged in Ii-dependent assembly of DPβ with DRα. We identified five members of a family of DPβ chains containing Lys-69 and GGPM 84-87, which assemble with DRα. The Lys/GGPM motif is present in the DPβ sequence of the Neanderthal genome, and this ancient sequence is related to the human allele DPB1*0401. By site-directed mutagenesis, we inspected Neanderthal amino acid residues that differ from the DPB1*0401 allele and aimed to determine whether matched heterodimers are formed by assembly of DPβ mutants with DRα. Because the *0401 allele is rare in the sub-Saharan population but frequent in the European population, it may have arisen in modern humans by admixture with Neanderthals in Europe.

Lymphoma immunotherapy with CpG oligodeoxynucleotides requires TLR9 either in the host or in the tumor itself

Established widely metastatic tumor was cured in a transplanted mouse B cell lymphoma model, by the combination of chemotherapy plus intratumoral injection of oligodeoxynucleotides containing unmethylated C-G motifs (CpG). This therapeutic effect required that the CpG be injected directly into the tumor and was dependent on CD8 T cells. Although the efficacy of CpG oligodeoxynucleotides has been thought to depend on the expression of TLR9, we unexpectedly found that tumor rejection did not require host expression of TLR9. By using a TLR9-deficient tumor and a TLR9KO host, we demonstrate that TLR9 expression either by the host or the tumor is required. These results indicate that activation of Ag presentation by cells within the tumor via TLR9 stimulation can be an effective form of immunotherapy. This study forms the basis of an ongoing clinical trial in patients with lymphoma.

Rafting MHC-II domains in the APC (presynaptic) plasma membrane and the thresholds for T-cell activation and immunological synapse formation

Glycosphingolipid- and cholesterol-rich membrane microdomains (rafts) in T-cells are important in triggering and regulation of T(H)-cell activation in immunological synapses (IS), which in turn may control the T-cell repertoire in lymph nodes and at the periphery. It is less known, however, how the "presynaptic side" controls formation and function of IS. We investigated here activation signals and synapse formation frequency of murine IP12-7 T(H) hybridoma cell specific to influenza virus HA-peptide upon stimulation with two B-lymphoma cells, A20 and 2PK3, pulsed with peptide antigen. Confocal microscopic colocalization and FRET data consonantly revealed clustered distribution and constitutive raft-association of a major fraction of MHC-II molecules in both APCs. Costimulatory molecules (CD80 and CD86), not associated constitutively with rafts, were expressed at much lower level in A20 cells. T-cells responded to 2PK3 APC with much higher signal strength than to A20 cells, in good correlation with the frequency of IS formation, as assessed by microscopic conjugation assay. Disruption of rafts by cholesterol depletion in 2PK3 cells largely decreased the magnitude of T(H) cell activation signals, especially at low peptide antigen doses, similarly to masking CD4 with mAb on T-cells. The frequency of IS formation was reduced by blocking LFA-1 on T-cells and CD80 on APCs, by lowering the temperature below the phase transition of the membrane or by disrupting actin cytoskeleton. These data together suggest that the surface density and affinity/stability of peptide-MHC-II complexes and the costimulatory level are primary determinants for an efficient TCR recognition and the strength of the subsequent T-cell signals, as well as of the IS formation, which additionally requires a cytoskeleton-dependent remodeling of APC surface after the initial TCR signal. The threshold of T-cell activation can be further set by rafting MHC-II domains via concentrating high affinity ligands and promoting thereby T-cells for sensing low density antigen. Our data also demonstrate that B-cells, similarly to dendritic cells, could also provide T-cells with antigen-independent weak survival signals, likely associated with integrin engagement.

Presentation of a viral peptide assembled on the carbohydrate moieties of immunoglobulin does not require processing

We have previously demonstrated that an immunodominant CD4 T cell epitope, HA110-120 of the hemagglutinin (HA) of the A/PR/8/34 influenza virus, enzymatically assembled on the carbohydrate moieties of self immunoglobulins (Ig) primed the precursors of peptide-specific T cells and induced efficient proliferation in vivo of naive lymphocytes from transgenic mice expressing the peptide-specific T cell receptor. Here, we show that an immuno-galacto-peptide construct, IgG-gal-HA, does not require intracellular or extracellular processing to present the peptide to the specific T cells. The presentation occurs following the binding of the IgG-gal-HA construct to Fc gamma receptor on the surface of antigen-presenting cells (APC), with concurrent interaction of the peptides to their neighboring major histocompatibility complex class II molecules. This mechanism of peptide presentation may harness the immune response in vivo by the engagement of APC with a low capacity of antigen processing, such as neonatal B cells. In addition, the enzymatic method of assembling various aminated compounds on the sugar moieties of Ig may offer novel perspectives on immuno-targeting of antagonist peptides, cytostatic drugs, and biologically active ligands of therapeutic use.

Peptide binding to mixed isotype Abeta(d)Ealpha(d) class II histocompatibility molecules

Previous studies have demonstrated that mixed isotype A beta(d) E alpha(d) molecules are expressed in transfected cell lines and that the level of expression is very low in normal B cells from H-2(d) mice. T-cell responses restricted by A beta(d) E alpha(d) are induced in H-2(d) mice immunized with the synthetic peptides YL2 and FL2 or with sperm whale myoglobin, despite the low concentration of mixed isotype molecules expressed on antigen-presenting cells. In the present study, the peptide binding behavior of A beta(d) E alpha(d) was investigated. A peptide from the cytoplasmic domain of invariant chain, I(1-18), was observed to bind with high affinity to purified A beta(d) E alpha(d). Binding was optimal at pH 5, indicating that these molecules prefer to bind peptide in the acidic environment of endosomal compartments similar to other murine class II proteins. YL2 and FL2 bind to A beta(d) E alpha(d) with slightly lower affinity. The selective restriction of YL2- and FL2-specific T cells to mixed isotype molecules was accounted for by the observation that these peptides do not bind to either I-E(d) or I-A(d). By contrast, myoglobin peptides bind to both parental and mixed isotype molecules. None of the A beta(d) E alpha(d)-restricted peptide determinants bind to A beta(d) E alpha(d) with extremely high affinity. Thus it is unlikely that these peptides occupy an unusually high fraction of mixed isotype molecules during antigen presentation in vivo. It is more likely that the presence of a subpopulation of high-affinity T cells capable of being stimulated by very low concentrations of A beta(d) E alpha(d)/peptide complexes is responsible for the unusual A beta(d) E alpha(d)-restricted response observed with some antigens.

Immunopotency of a viral peptide assembled on the carbohydrate moieties of self immunoglobulins

The T-cell receptor recognizes peptides bound to the major histocompatibility complex antigens. Synthetic peptides corresponding to microbial epitopes can efficiently stimulate the in vitro proliferation of T-cell hybridoma or in vivo primed T cells. However, the in vivo immune responses elicited by synthetic peptides are weak because of their short half-life and poor immunogenicity. We previously showed that a genetically engineered immunoglobulin (Ig-HA), in which the CDR3 region of VH gene was replaced with a viral peptide recognized by CD4+ T cells, was able to deliver this epitope in the correct frame to antigen-processing cells that efficiently presented the peptide to T cells. Recently, we developed an enzymatic method to assemble viral peptides on the sugar moieties of immunoglobulins without alteration of the biological functions of either molecule. The viral peptide carried by these conjugates was twenty times more efficient in activating a T-cell hybridoma than the free peptide as calculated on a molar basis. We show that such conjugates are able to prime in vivo the precursors of peptide-specific T cells and to induce proliferation of naive lymphocytes from transgenic mice expressing a peptide-specific T-cell receptor in both CD4 and CD8 T-cell subsets. Our results suggest that peptides enzymatically linked to the carbohydrate moieties of immunoglobulins, using galactose residues as peptide acceptor, can be used as a safe and efficient delivery system of protective epitopes for the prevention of infectious diseases. The enzymatic engineering of immunoglobulins may also allow the development of immunotherapeutic agents to deliver antagonist peptides to autoreactive T cells or to direct immunomodulatory agents such as interleukins or cytolytic drugs to tumor cells.

Peptide-specific activation of cytolytic CD4+ T lymphocytes against tumor cells bearing mutated epitopes of K-ras p21

Alterations in the ras p21 protein have been associated with both rodent and human neoplasia. Thus, mutated ras p21 proteins may bear unique antigenic epitopes for immune recognition, such as by T cells, which have been implicated in host antitumor activity. Synthetic peptides that mimic segments of mutated ras p21 have been reported to be immunogenic in mice in vivo, although detailed functional analyses remains undefined. Here, in a murine model, we explored and characterized distinct effector properties of host-derived T lymphocytes reactive to mutated ras peptides, which was consistent with the CD4+ T helper type 1 (Th1) subset. BALB/c mice (H-2d) were immunized with a purified peptide, 13 amino acids in length, containing the substitution of Gly (G12) to Val (V12) at position 12, which is commonly found in human carcinomas. An alpha beta T cell receptor-positive, CD3+, CD4+, CD8- T cell line was established, which expressed peptide-specific proliferation. Cytokine assays revealed the production of interleukin-2, interferon-gamma, tumor necrosis factor and granulocyte-macrophage colony-stimulating factor. Moreover, antigen-specific cytotoxicity was demonstrable against: (1) Iad-bearing A20 tumor cells incubated with exogenously bound V12 peptide; and (2) A20 tumor cells transduced with the K-ras p21 oncogene encoding the corresponding point mutation. CD4(+)-mediated cytotoxicity was major histocompatibility complex (MHC) class II-restricted, as revealed by the absence of lysis against MHC class II- P815 targets, inhibition of A20 lysis with anti-Iad monoclonal antibodies, and induction of lysis against L cell targets transfected with E alpha A beta d. Independent isolation of a second CD4+ V12 line revealed a very similar cytolytic and MHC class II-restricted profile. Overall, these data demonstrated that peptide immunization produced a CD4+ Th1 response that specifically recognized tumor cells expressing endogenous activated K-ras epitopes, which may have implications for the development of peptide-based active immunotherapies.

Presentation of antigen by mixed isotype class II molecules in normal H-2d mice

A panel of DBA/2 T cell hybridomas specific for the sperm whale myoglobin epitope 110-121 was found to recognize antigen presented by the mixed isotype class II molecule E alpha dA beta d. The response was blocked by monoclonal antibodies specific for E alpha and A beta d chains; in addition, the hybridomas responded to antigen presented by L cells expressing E alpha A beta d molecules, and made no response with L cells expressing I-Ad or I-Ed molecules. Two more groups of hybridomas isolated from DBA/2 and B10.D2 mice immunized with myoglobin also recognized peptide 110-121 presented by E alpha d A beta d. Thus, although it is expressed at biochemically undetectable levels on spleen cells, the E alpha d A beta d molecule is an important presenting element in normal H-2d mice making a conventional immune response to a protein antigen. These results suggest that high levels of class II expression are not a prerequisite for T cell activation.

Surface expression of a T cell receptor beta (TCR-beta) chain in the absence of TCR-alpha, -delta, and -gamma proteins

The antigen receptor expressed by mature T cells has been described as a disulfide-linked alpha/beta or gamma/delta heterodimer noncovalently associated with CD3, a complex of transmembrane proteins that communicates signals from the T cell receptor (TCR) to the cell interior. Studies suggest that all component chains must assemble intracellularly before surface expression can be achieved. We described, however, a CD4+/CD8+ transformed murine thymocyte, KKF, that expresses surface TCR-beta chains in the absence of gamma, delta, and alpha proteins; these beta chains are only weakly associated with CD3-epsilon and CD3-zeta. Furthermore, KKF responds differently to stimulation through TCR-beta and CD3-epsilon, a functional dissociation that has been ascribed to a CD4+/CD8+ subpopulation of normal thymocytes. KKF's unique TCR structure may offer an explanation for the functional anomalies observed.

Mice lacking MHC class II molecules

We have produced mice that lack major histocompatibility complex class II antigens, permitting us to evaluate the role of these molecules in diverse aspects of T and B cell differentiation. The mutant mice show near-complete elimination of CD4+ T lymphocytes from the spleen and lymph nodes; the few remaining CD4-positive cells are preferentially localized to B cell follicles. Surprisingly, substantial numbers of CD4 single-positive cells reside in the thymus; however, these are not mature thymocytes as we currently recognize them. B lymphocytes occur in normal numbers and are capable of terminal differentiation to plasma cells. Nevertheless, several aberrations in the B cell compartment are demonstrable: a lack of germinal centers, fewer IgM+IgD+ cells in certain individuals, reduced production of serum IgG1, and complete inability to respond to T-dependent antigens. In short, the class II-negative mice have confirmed some old ideas about lymphocyte differentiation, but have provided some surprises.

A novel class II MHC molecule with unusual tissue distribution

The repertoire of mature class II-restricted T cells is generated through a complex process of selection whereby early T cells confront class II molecules in the thymus, especially on epithelial cells. Expression of class II molecules on such cells is prominent both in the cortex and in the medulla. We have identified a novel class II molecule, H-20, which is expressed only in epithelial cells of the thymic medulla and in B cells. The unusual tissue distribution and the nonpolymorphic nature of H-20 suggest that its function is different from that of classical class II molecules.

Human HLA-DQ beta chain presents minor lymphocyte stimulating locus gene products and clonally deletes TCR V beta 6+, V beta 8.1+ T cells in single transgenic mice

Minor lymphocyte stimulating locus (Mls) gene products in association with mouse major histocompatibility complex (MHC) class II molecules are known to determine the repertoire of T-cell receptor (TCR) in mature T cells. In order to test whether human class II molecules can present mouse Mls, HLA-DQ beta transgenic mice were generated. The expression and function of the DQ beta transgene were studied in the progeny of one selected founder which was H-2f and H-2E negative. In these mice, DQ beta molecules pairing with mouse A alpha chain and invariant chain are expressed on the cell surface in a tissue-specific manner. When the DQ beta gene was bred into the Mls-1a strain DBA/1 (H-2q), T cells bearing V beta 6 and V beta 8.1 TCR were clonally deleted in the thymus of DQ beta+ transgenics but not in DQ beta-negative full sibs. Thus, the data presented here clearly demonstrate that the human MHC DQ beta chain can present Mls in the clonal deletion of T cells. Our results also suggest the requirement for an interaction between CD4 and class II molecules (alpha chain) for clonal deletion of T cells to occur.

Inhibition of T cell receptor expression and function in immature CD4+CD8+ cells by CD4

Most immature CD4+CD8+ thymocytes express only a small number of T cell receptor (TCR) molecules on their surface, and the TCR molecules they do express are only marginally capable of transducing intracellular signals. TCR expression and function was not intrinsically low in immature CD4+CD8+ thymocytes, but was found to be actively inhibited by CD4-mediated signals. Indeed, release of CD4+CD8+ thymocytes from CD4-mediated signals resulted in significant increases in both TCR expression and signaling function. These results suggest that, in CD4+CD8+ cells developing in the thymus, increased TCR expression and function requires release from CD4-mediated inhibition.

The minimal number of class II MHC-antigen complexes needed for T cell activation

Major histocompatibility complex (MHC) molecules are exposed to large quantities of self and nonself antigens. It is not known what fraction of MHC molecules needs to be occupied by antigen to induce a T cell response. A quantitative study of naturally processed antigen indicated that T cells could be activated when only 0.03 percent of the total I-Ed purified from antigen-presenting cells (APCs) was occupied with antigen. B cells and macrophages processed hen egg lysozyme (HEL) with different efficiencies, but similar degrees of occupancy were required for T cell stimulation. Higher occupancy was needed for I-Ed-transfected L cells, possibly reflecting the requirement for other accessory molecules for efficient APC-T cell interaction.

Existence of mixed isotype A beta E alpha class II molecules in Ed alpha gene-introduced C57BL/6 transgenic mice

In this study the existence of mixed isotype Ab beta Ed alpha molecules in Ed alpha gene-introduced C57BL/6 (B6Ed alpha) transgenic mice is demonstrated. Biosynthetically labelled B6Ed alpha transgenic spleen cells were immunoprecipitated with anti-Ab beta or anti-Ed alpha monoclonal antibody (mAb) and analysed by two-dimensional gel electrophoresis (NEPHGE/SDS-PAGE). Anti-Ab beta mAb precipitated Ed alpha molecules in addition to Ab beta and Ab alpha molecules. Anti-Ed alpha mAb precipitated Ab beta molecules in addition ot Eb beta and Ed alpha molecules. No Ed alpha molecule was precipitated by anti-Ab beta mAb from B10.A(3R) spleen cells, which have a very similar organization of class II molecules to B6Ed alpha transgenic mice. Since this B6Ed alpha transgenic mouse was shown to have 20-40 copies per cell of the Ed alpha transgene (Kashiwamura et al., 1988), it is speculated that large amounts of Ed alpha transgene are made but, according to the data presented here, only a small amount actually associates with Ab beta as opposed to Eb beta.

Structural requirements for pairing of alpha and beta chains in HLA-DR and HLA-DP molecules

To test for the assembly of human MHC class II molecules having an alpha chain from one isotype (HLA-DR, -DQ, or -DP) and the beta chain of another (mixed isotypic pairs), murine fibroblasts were transfected with expressible cDNAs encoding the different class II alpha and beta chains. A rapid and efficient transient transfection system was developed using a polyoma virus-based vector. Typically, 30-50% of cells transfected using this system expressed high levels of class II molecules on their surface, but only with matched isotypic pairs. Biochemical analysis of cells transfected with matched or mixed isotypic pairs of the DR and DP molecules revealed that only matched chains could pair efficiently inside the cell. Thus, the lack of expression of the two mixed isotypic pairs is due to inefficient primary assembly of the class II molecule and not to a processing or transport defect. To define what region of the beta chains controlled their assembly with alpha chains, a series of chimeric cDNA molecules containing both DR and DP beta chain sequences were constructed. Expression of these chimeric beta chains with DR and DP alpha chains was determined by cytofluorimetry and biochemical analysis. Both alpha chains paired with beta chains in which only the beta 1 domain was isotypically matched. In contrast, the pattern of expression of chimeras made at other points within the beta 1 domain was different for DR and DP. These data show that different areas of primary sequence are important for the assembly of different human class II isotypes, and suggest that HLA-DR and -DP molecules have different secondary or tertiary structures in their NH2-terminal domains.

Antigen-reactive T cell clones restricted by mixed isotype A beta d/E alpha d class II molecules

Mixed isotype A beta dE alpha d class II molecule-restricted antigen-reactive T cell clones were obtained from (BALB/c x B6E alpha d)F1 mice. These T cell clones responded to keyhole limpet hemocyanin in the presence of (BALB/c x B6E alpha d)F1 but not CBF1 APCs. Both anti-A beta d and anti-E alpha mAbs blocked the proliferative responses of these clones. The frequency of such mixed isotype A beta E alpha-restricted T cell clones in (BALB/c x B6E alpha d)F1 mice was estimated to be approximately 10% from our limiting dilution cloning. The existence of such mixed isotype class II molecule-restricted T cells would have important implications for the expansion of the T cell repertoire as well as the induction of autoimmunity.

In vivo expression and function of hybrid Ia dimers (E alpha A beta) in recombinant and transgenic mice

We have found cell surface expression of an E alpha molecule in recombinant and transgenic mouse strains lacking an E beta molecule. Flow cytometry has shown low level expression of E alpha in B10.RQB3 (I-AqEk alpha) and B10.RFB2 (I-AfEk alpha) mice. We have also found that B10.Q (H-2q) mice can express the Ek alpha transgene. Since these strains do not have functional E beta chains, we propose that the E alpha A beta hybrid dimers are formed in low numbers and can be picked up by FACS analysis. So far we have not been able to identify these hybrid molecules by cytotoxicity or immunoprecipitation. The E alpha/A beta molecule can function in vivo during thymic selection in the clonal deletion of two V beta TCR subsets, V beta 11 and V beta 6, which have been shown to interact with the intact I-E molecule.

Role of MHC, Mls and TCR in immune tolerance

MHC class II molecules and self antigens, such as Mls, influence T-cell selection by clonal deletion of potentially self-reactive T cells. In order to examine the role of various class II molecules in the T-cell receptor-self antigen interaction, class II transgenic and recombinant mice were analysed for TCR expression. Our studies indicate that the A alpha and E alpha chains can present Mls gene products for the clonal deletion of V beta 6-bearing T cells, and that the A alpha q chain is defective in this process. We have also shown that E alpha A beta heterodimer in transgenic and recombinant mice is expressed and functions to delete I-E reactive V beta llT cells, demonstrating again the role of the E alpha molecule.