The tetraspanin CD9 mediates lateral association of MHC class II molecules on the dendritic cell surface

We have found that MHC class II (MHC II) molecules exhibit a distinctive organization on the dendritic cell (DC) plasma membrane. Both in DC lysates and on the surface of living cells, I-A and I-E molecules engaged in lateral interactions not observed on other antigen-presenting cells such as B blasts. Because DCs and B blasts express MHC II at comparable surface densities, the interaction was not due to simple mass action. Instead, it reflected the selective expression of the tetraspanin CD9 at the DC surface. I-A and I-E molecules coprecipitated with each other and with CD9. The association of heterologous MHC II molecules was abrogated in DCs from CD9(-/-) mice. Conversely, expression of exogenous CD9 in B cells induced MHC II interactions. CD9 is thus necessary for the association of heterologous MHC II, a specialization that would facilitate the formation of MHC II multimers expected to enhance T cell receptor stimulation by DCs.     

Altered positive selection due to corecognition of floppy peptide/MHC II conformers supports an integrative model of thymic selection

Thymocytes bearing the E alpha 52-68/I-A(b) complex-specific 1H3.1 alpha beta T cell antigen receptor are positively selected in Ab-Ep [Ab-Ep transgenic, invariant chain (Ii)(-/-), I-A beta(b-/-)] mice, where I-A(b) molecules present only E alpha 52-68. Although Ii reintroduction led to deletion, I-A beta(b) reintroduction disrupted positive selection. T cell antigen receptor transgenic Ab-Ep I-A beta(b+) mice had a large thymus with an increased absolute number of CD4(+)CD8(+) cells and no overt signs of deletion. Unlike Ab-Ep Ii(+) antigen-presenting cells, Ab-Ep I-A beta(b+) antigen-presenting cells did not activate 1H3.1 T cells. However, their capacity to present E alpha 52-68 was intact. Thus, positive selection of 1H3.1 thymocytes on the tight compact E alpha 52-68/I-A(b) complex is neutralized by the corecognition of loose compact self-peptide/I-A(b) conformers that do not interfere with the cognate activation of mature 1H3.1 T cells. The data support the notion that the integration of distinct signals generated by the simultaneous recognition of multiple self-peptide/MHC complexes directs intrathymic selection of T cells.     

Self-recognition is crucial for maintaining the peripheral CD4+ T-cell pool in a nonlymphopenic environment

The role of self-recognition in the maintenance of the peripheral CD4+ T-cell pool has been extensively studied, but no clear answer has so far emerged. Indeed, in studies of the role of self-major histocompatibility complex (MHC) molecules in CD4+ T-cell survival, several parameters must be taken into account when interpreting the results: (1) in a lymphopenic environment, observations are biased by concomitant proliferation of T cells arising in MHC-expressing mice; (2) the peripheral T-cell compartment is qualitatively and quantitatively different in nonlymphopenic, normal, and MHC class II-deficient mice; and (3) in C57BL/6 Abeta(-/-) mice (traditionally considered MHC class II-deficient), the Aalpha chain and the Ebeta chain associate to form a hybrid AalphaEbeta MHC class II molecule. In light of these considerations, we revisited the role of interactions with MHC class II molecules in the survival of peripheral CD4+ T cells. We found that the answer to the question "is self-recognition required for CD4+ T cells to survive?" is not a simple yes or no. Indeed, although long-term survival of CD4+ T cells does not depend on self-recognition in lymphopenic mice, interactions with MHC class II molecules are required for maintaining the peripheral CD4+ T-cell pool in a nonlymphopenic environment.     

Major histocompatibility complex class I-restricted activation of cloned T cells by a soluble protein in the absence of accessory cells

A T-cell clone, 10BK.1, was established from the draining lymph nodes of (B10 x B10.BR)F1 mice immunized with ovalbumin (OVA) according to standard protocols. Upon coculture with the antigen, 10BK.1 cells reacted by production of lymphokines and by proliferation despite the absence of additional antigen-presenting cells. These T cells do not express major histocompatibility complex (MHC) class II molecules on the cell surface as assessed on the basis of several criteria: by cytofluorometric analysis I-A and I-E determinants were not detectable; 10BK.1 cells could not act as antigen-presenting cells for long-term-cultured MHC class II-restricted T-cell clones; and monoclonal antibodies directed at both MHC class II isotypic complexes (I-A, I-E) did not suppress their OVA-induced activation. In contrast, proliferation of 10BK.1 T cells in response to OVA was abrogated by antibodies directed at H-2Kb antigens. Inhibition experiments employing antibodies directed at Lyt-2 and L3T4 antigens in addition to cytofluorometric analysis revealed that T-cell clone 10BK.1 exhibits the Thy-1+,Lyt-2+,Ly-1-,L3T4- phenotype. 10BK.1 cells pulsed with OVA and fixed with glutaraldehyde induced proliferation of untreated 10BK.1 cells. These data support the theory that 10BK.1 T cells present the exogenous globular protein OVA to one another in an MHC class I-restricted manner, resulting in cell activation and proliferation independent of added accessory cells.     

Genetic control of immune response to a purified Schistosoma mansoni antigen. II. Establishment and characterization of specific I–A and I–E restricted T–cell clones

T-cell lines and clones specific for a partially protective schistosome antigen (9B antigen) were established from mice immunized with such antigen. The H-2 congenic strains B10.A which express both I-A and I-E class II gene products of the major histocompatibility complex (MHC) and B10.A(4R) which only express I-A molecules were used in these studies. The specific T-cell lines recognized the 9B antigen in the context of either A or E molecules, but both class II antigens were necessary for maximal stimulation of the T-cell lines in lymphocyte proliferation assays. T-cell clones were derived from these lines and their MHC restriction was investigated. Both I-A and I-E restricted clones could be isolated. All clones were specific for 9B antigen showing different degrees of cross-reactivity with a total schistosome extract (CA sonicate). A correlation between the fine specificity of the clones and the expression of class II antigens was demonstrated. Clones specific for 9B antigen, or which reacted to the same extent with 9B antigen and CA sonicate, were I-A restricted, whereas clones which proliferated more in the presence of CA sonicate were all I-E restricted. This suggests that I-E restricted clones recognize more cross-reactive epitopes than I-A restricted clones. These antigen-specific T-cell clones should provide a useful tool for examining the role of class II antigens in the modulation of protective immune response during Schistosoma mansoni infection.     

Detection of glutamic acid decarboxylase-activated T cells with I-Ag7 tetramers

CD4(+) T cells selected by the type 1 diabetes associated class II MHC I-A(g7) molecules play a critical role in the disease process. Multivalent MHC/peptide tetramers have been used to directly detect antigen-specific T cells. Detection of autoantigen-activated CD4(+) T cells with tetramers should be very helpful in the study of the roles of these cells in diabetes. We report here the generation of tetramers of I-A(g7) covalently linked to two glutamic acid decarboxylase (GAD) peptides and the detection of GAD peptide-activated T cells from nonobese diabetic (NOD) mice. The I-A(g7) heterodimers can form stable complexes with a covalently bound GAD peptide and can stimulate antigen specific T cells. Furthermore, I-A(g7)/GAD peptide tetramer can detect most if not all of the antigen-specific CD4(+) T cells from immunized NOD mice. Antigen-specific T cells detected by the tetramers can up-regulate their CD4 expression on the cell surface after being restimulated with the GAD peptides in vitro. In contrast, the tetramers can detect a percentage of T cells in lymph nodes and spleens and T cells infiltrating islets from nonimmunized mice that is not significantly above the background. Therefore, T cells specific for the GAD peptides are present in NOD mice at a frequency too low to be detected, but immunization of NOD mice can facilitate their detection by tetramers.     

Paradoxical intrathymic positive selection in mice with only a covalently presented agonist peptide

The Y-Ae mAb and the 1H3.1 alphabeta T cell antigen receptor (TCR) are both specific for the I-Ealpha52-68 peptide bound to the I-A(b) major histocompatibility complex (MHC) class II molecule. Antigen-presenting cells (APCs) from I-A(b+) mice with a natural or transgenic (Tg) I-Ealpha chain activate mature 1H3.1 T cells and cause the deletion of 1H3.1 TCR Tg thymocytes. However, 1H3.1 T cells were neither activated nor inactivated by confrontation with APCs from I-Ab-Ep mice in which I-A(b) molecules are occupied only by the covalently associated Ealpha52-68 peptide. Instead, immature 1H3.1 TCR Tg thymocytes were efficiently positively selected into the CD4 lineage in the I-Ab-Ep thymus. This selection relied on specific recognition of the Ealpha52-68/I-A(b) complex because it was blocked by Y-Ae. 1H3.1 TCR Tg T cells maturing in the I-Ab-Ep thymus efficiently populated the periphery, displayed a naive phenotype, and were specifically reactive to the Ealpha52-68 peptide or to I-A(b+)I-Ealpha(+) APCs, indicating that 1H3.1 T cells were not antagonized in I-Ab-Ep mice. The data identify major histocompatibility complex class II molecules with only a covalently attached self-peptide as a ligand for in vivo positive selection of T cells specific for the same peptide.     

Expression of HLA-DR4 and human CD4 transgenes in mice determines the variable region beta-chain T-cell repertoire and mediates an HLA-DR-restricted immune response.

Inherited susceptibility to rheumatoid arthritis is associated with genes encoding the human major histocompatibility complex class II molecule HLA-DR4. To study the immune function of HLA-DR4 and attempt to generate a murine model of rheumatoid arthritis we have produced triple transgenic mice expressing HLA-DRA*0101, -DRB1*0401, and human CD4. The expression of the HLA transgenes is driven by the promoter of the murine major histocompatibility complex class II I-E alpha gene and was found on murine cells that normally display major histocompatibility complex class II molecules. The expression of the human CD4 transgene is driven by the murine CD3 delta-promoter, and therefore its gene product was found on cells that express murine CD3. In contrast to other HLA-DR and HLA-DQ transgenic mouse lines, the transgenes are functional in our mice. In H-2 I-E-negative transgenic mice, T cells expressing variable region beta chain (V beta) 3, 5, 6, 7, 9, 11, 12, or 13 were either absent or significantly reduced, in contrast to H-2 I-E-negative nontransgenic littermates. In addition, the peptide antigen influenza A virus hemagglutinin 307-319, which binds to the HLA-DRA*0101/-DRB1*0401 heterodimer with high affinity and induces an HLA-DR-restricted and CD4+ T-cell response in humans, also induced a T-cell response in the triple transgenic mice but not in nontransgenic littermates. Thus, these transgenic mice should permit extensive testing of the antigen-presentation capabilities of the HLA-DRA*0101/-DRB1*0401 molecule.     

Alpha4 and beta2 integrins have nonredundant roles for asthma development, but for optimal allergen sensitization only alpha4 is critical

OBJECTIVE: Recruitment of effector cell subsets to inflammatory lung, together with airway resident cells responsive to secreted products, play pivotal roles in developing and maintaining asthma. Differential use of adhesion molecules dictates the recruitment patterns of specific cell subsets, yet a clear understanding of the distinctive adhesive molecular pathways guiding them to lung is lacking. To provide further insight into the role of alpha4beta1/VCAM-1 pathway and to compare this to the role of beta2 integrin in the development of acute asthma phenotype, we used genetically deficient mice, in contrast to previous studies with anti-functional antibodies yielding ambiguous results. METHODS: Allergen-dependent airway inflammation and hyperresponsiveness was induced in conditional alpha4(Delta/Delta), VCAM-1(-/-), and beta2(-/-) mice. Cytology, immunocytochemistry, cytokine and immunoglobulin measurements, and cell type accumulation in lung, BAL fluid, plasma, and hemopoietic tissues were carried out. RESULTS: Asthma phenotype was totally abrogated in alpha4- or beta2-deficient mice. Adoptive transfer of sensitized alpha4(Delta/Delta) CD4(+) cells into challenged normal mice failed to induce asthma, whereas alpha4(+/+) CD4(+) cells were able to induce asthma in challenged alpha4(Delta/Delta) mice. Parallel studies with beta2(-/-) or VCAM-1(-/-) mice uncovered novel mechanistic insights in primary sensitization and into redundant or unique functional roles of these adhesion pathways in allergic asthma. CONCLUSIONS: The lack of alpha4 integrin not only impedes the migration of all white cell subsets to lung and airways, but also prevents upregulation of vascular cell adhesion molecule-1 (VCAM-1) in inflamed lung vasculature and, unlike beta2, attenuates optimal sensitization and ovalbumin-specific IgE production in vivo. As VCAM-1 deficiency did not protect mice from asthma, interactions of alpha4beta1(+) or alpha4beta7(+) cells with other ligands are suggested.     

Differential induction of major histocompatibility complex molecules on mouse intestine by bacterial colonization.

The aim of this study was to determine what factors induce major histocompatibility complex (MHC) molecules on the mouse small intestinal epithelium by using immunohistochemical methods. In germ-free mice, although MHC class I molecules such as H-2K and thymus leukemia antigen (TLa) were expressed on the small intestinal epithelium, class II molecules were absent. The introduction of microorganisms into germ-free mice induced characteristic MHC molecules on the small intestinal epithelial cells. The I-A molecule was induced on the villus tip and crypt epithelial cells 7 days after conventionalization, and the I-E molecule was induced on the mid villus and crypt epithelial cells 14 days after conventionalization. The staining intensity of the H-2K molecules was increased 4 days after conventionalization. In contrast, TLa did not change during conventionalization of germ-free mice. These results suggest that the expression of MHC molecules, except for the TLa, is greatly dependent on the presence of intestinal microorganisms.     

CD4+ T-cell epitopes associated with antibody responses after intravenously and subcutaneously applied human FVIII in humanized hemophilic E17 HLA-DRB1*1501 mice

Today it is generally accepted that B cells require cognate interactions with CD4(+) T cells to develop high-affinity antibodies against proteins. CD4(+) T cells recognize peptides (epitopes) presented by MHC class II molecules that are expressed on antigen-presenting cells. Structural features of both the MHC class II molecule and the peptide determine the specificity of CD4(+) T cells that can bind to the MHC class II-peptide complex. We used a new humanized hemophilic mouse model to identify FVIII peptides presented by HLA-DRB1*1501. This model carries a knockout of all murine MHC class II molecules and expresses a chimeric murine-human MHC class II complex that contains the peptide-binding sites of the human HLA-DRB1*1501. When mice were treated with human FVIII, the proportion of mice that developed antibodies depended on the application route of FVIII and the activation state of the innate immune system. We identified 8 FVIII peptide regions that contained CD4(+) T-cell epitopes presented by HLA-DRB1*1501 to CD4(+) T cells during immune responses against FVIII. CD4(+) T-cell responses after intravenous and subcutaneous application of FVIII involved the same immunodominant FVIII epitopes. Interestingly, most of the 8 peptide regions contained promiscuous epitopes that bound to several different HLA-DR proteins in in vitro binding assays.     

Functional comparison of thymic B cells and dendritic cells in vivo

In this report we present a transgenic mouse model in which we targeted gene expression specifically to B-lymphocytes. Using the human CD19 promoter, we expressed major histocompatibility complex class II I-E molecules specifically on B cells of all tissues, but not on other cell types. If only B cells expressed I-E in a class II-deficient background, positive selection of CD4(+) T cells could not be observed. A comparison of the frequencies of I-E reactive Vbeta5(+) and Vbeta11(+) T cells shows that I-E expression on thymic B cells is sufficient to negatively select I-E reactive CD4(+) T cells partially, but not CD8(+) T cells. Thus partial negative but no positive selection events can be induced by B-lymphocytes in vivo. (Blood. 2000;95:2610-2616)     

Antigen presentation by keratinocytes directs autoimmune skin disease

The antigen-presenting cells that initiate and maintain MHC class II-associated organ-specific autoimmune diseases are poorly defined. We now describe a new T cell antigen receptor (TCR) transgenic (Tg) model of inflammatory skin disease in which keratinocytes activate and are the primary target of autoreactive CD4(+) T cells. We previously generated keratin 14 (K14)-A(beta)b mice expressing MHC class II only on thymic cortical epithelium. CD4(+) T cells from K14-A(beta)b mice fail to undergo negative selection and thus have significant autoreactivity. The TCR genes from an autoreactive K14-A(beta)b CD4 hybridoma were cloned to produce a TCR Tg mouse, 2-2-3. 2-2-3 TCR Tg cells are negatively selected in WT C57BL6 mice but not in 2-2-3K14-A(beta)b mice. Interestingly, a significant number of mice that express both the K14-A(beta)b transgene and the autoreactive 2-2-3 TCR spontaneously develop inflammatory skin disease with mononuclear infiltrates, induction of MHC class II expression on keratinocytes, and T helper 1 cytokines. Disease can be induced by skin inflammation but not solely by activation of T cells. Thus, cutaneous immunopathology can be directed through antigen presentation by tissue-resident keratinocytes to autoreactive TCR Tg CD4(+) cells.     

Binding of an invariant-chain peptide, CLIP, to I-A major histocompatibility complex class II molecules.

Invariant chain (Ii) associates with major histocompatibility complex (MHC) class II molecules and is crucial for antigen presentation by class II molecules. The exact nature of Ii interaction with MHC class II molecules remains undefined. A nested set of Ii peptides, CLIPs (class II-associated Ii peptides), have been eluted from various MHC class II molecules, suggesting that CLIPs correspond, at least in part, to the Ii motif which blocks the conventional peptide binding site in MHC class II molecules. Here we report how CLIPs interact with class II MHC molecules, I-A. We have identified regions critical for binding of CLIPs and I-A class II molecules. In most cases, the binding of CLIPs to a number of I-A molecules is modulated by the steric bulk of methionine residues at positions 93 and 99. In addition, the binding of CLIPs to an I-A molecule, I-Au, is sensitive to substitutions at aspartic acid-59 in the alpha chain and threonine-86 in the beta chain, whereas the binding of an antigen-derived peptide is not. Taken together, these results provide an insight as to how CLIPs bind to MHC class II heterodimers.     

Prevalent CD8+ T cell response against one peptide/MHC complex in autoimmune diabetes

Spontaneous autoimmune diabetes in nonobese diabetic (NOD) mice is the result of a CD4(+) and CD8(+) T cell-dependent autoimmune process directed against the pancreatic beta cells. CD8(+) T cells play a critical role in the initiation and progression of diabetes, but the specificity and diversity of their antigenic repertoire remain unknown. Here, we define the structure of a peptide mimotope that elicits the proliferation, cytokine secretion, differentiation, and cytotoxicity of a diabetogenic H-2K(d)-restricted CD8(+) T cell specificity (NY8.3) that uses a T cell receptor alpha (TCRalpha) rearrangement frequently expressed by CD8(+) T cells propagated from the earliest insulitic lesions of NOD mice (Valpha17-Jalpha42 elements, often joined by the N-region sequence M-R-D/E). Stimulation of splenic CD8(+) T cells from single-chain 8. 3-TCRbeta-transgenic NOD mice with this mimotope leads to preferential expansion of T cells bearing an endogenously derived TCRalpha chain identical to the one used by their islet-associated CD8(+) T cells, which is also identical to the 8.3-TCRalpha sequence. Cytotoxicity assays using islet-derived CD8(+) T cell clones from nontransgenic NOD mice as effectors and peptide-pulsed H-2K(d)-transfected RMA-S cells as targets indicate that nearly half of the CD8(+) T cells recruited to islets in NOD mice specifically recognize the same peptide/H-2K(d) complex. This work demonstrates that beta cell-reactive CD8(+) T cells mount a prevalent response against a single peptide/MHC complex and provides one peptide ligand for CD8(+) T cells in autoimmune diabetes.     

Major histocompatibility complex class I-specific and -restricted killing of beta 2-microglobulin-deficient cells by CD8+ cytotoxic T lymphocytes.

Cytotoxic T lymphocytes (CTLs) recognize major histocompatibility complex (MHC) class I molecules, normally composed of a heavy chain, a beta 2-microglobulin (beta 2m), and peptide antigens. beta 2m is considered essential for the assembly and intracellular transport of MHC class I molecules as well as their peptide presentation to CTLs. Contrary to this dogma, we now report the generation of allospecific and restricted CD8+ and TCR alpha beta+ CTLs (where TCR is T-cell receptor) capable of killing beta 2m-deficient cells. Such CTLs were obtained by priming mice with live allogeneic beta 2m- spleen cells or mutant lymphoma cells producing MHC class I protein but no detectable beta 2m. Although both beta 2m- and beta 2m-expressing lymphoma cells were rejected in allogeneic mice, only the former were efficient inducers of CTLs recognizing beta 2m- cells. These CTLs were MHC class I (H-2Kb or Db)-specific and CD8-dependent and did not require serum as a source of external beta 2m in the culture. They could be induced across major and minor histocompatibility barriers. The H-2-restricted CTLs generated in the latter case failed to kill the antigen-processing-deficient target RMA-S cells. The results show that MHC class I heavy chains in beta 2m- cells can be transported to the cell surface and act as antigens or antigen-presenting molecules to allospecific and MHC-restricted CTLs.     

Development of CD4+ T cells expressing a nominally MHC class I-restricted T cell receptor by two different mechanisms

Differences in T cell receptor (TCR) signaling initiated by interactions among TCRs, coreceptors, and self-peptide-MHC complexes determine the outcome of CD4 versus CD8 lineage of T cell differentiation. The H-2Ld and Kbm3 alloreactive 2C TCR is positively selected by MHC class I Kb and a yet-to-be identified nonclassical class I molecule to differentiate into CD8+ T cells. Here we describe two mechanisms by which CD4+ 2C T cells can be generated in 2C TCR-transgenic mice. In the RAG-/- background, development of CD4+ 2C T cells requires the expression of both I-Ab and the TAP genes, indicating that both MHC class I and II molecules are required for positive selection of these T cells. Notably, only some of the 2C+ RAG-/- mice (approximately 30%) develop CD4+ 2C T cells, with frequencies in individual mice varying from 0.5% to as high as approximately 50%. In the RAG+ background, where endogenous TCRalpha genes are rearranged and expressed, CD4+ 2C T cells are generated because these cells express the 2C TCR as well as additional TCRs, consisting of the 2C TCRbeta and endogenous TCRalpha chains. Similarly, T cells expressing the OT-1 TCR, which is nominally MHC class I-restricted, can also develop into CD4+ T cells through the same two mechanisms. Thus, expression of two TCRs by a single thymocyte, TCR recognition of multiple MHC molecules, and heterogeneity of TCR, coreceptors, and peptide-MHC interactions in the thymus all contribute to the outcome of CD4 versus CD8 lineage development.     

Postexposure vaccination massively increases the prevalence of gamma-herpesvirus-specific CD8+ T cells but confers minimal survival advantage on CD4-deficient mice

Mice that lack CD4(+) T cells remain clinically normal for more than 60 days after respiratory challenge with the murine gamma-herpesvirus 68 (gammaHV-68), then develop symptoms of a progressive wasting disease. The gammaHV-68-specific CD8(+) T cells that persist in these I-A(b-/-) mice are unable to prevent continued, but relatively low level, virus replication. Postexposure challenge with recombinant vaccinia viruses expressing gammaHV-68 lytic cycle epitopes massively increased the magnitude of the gammaHV-68-specific CD8(+) population detectable by staining with tetrameric complexes of MHC class I glycoprotein + peptide, or by interferon-gamma production subsequent to in vitro restimulation with peptide. The boosting effect was comparable for gammaHV-68-infected I-A(b-/-) and I-A(b+/+) mice within 7 days of challenge, and took more than 110 days to return to prevaccination levels in the I-A(b+/+) controls. Although the life-span of the I-A(b-/-) mice was significantly increased, there was no effect on long-term survival. A further boost with a recombinant influenza A virus failed to improve the situation. Onset of weight loss was associated with a decline in gammaHV-68-specific CD8(+) T cell numbers, though it is not clear whether this was a cause or an effect of the underlying pathology. Even very high levels of virus-specific CD8(+) T cells thus provide only transient protection against the uniformly lethal consequences of gammaHV-68 infection under conditions of CD4(+) T cell deficiency.     

CD4(+) T cells eliminate MHC class II-negative cancer cells in vivo by indirect effects of IFN-gamma.

CD4(+) T cells can eliminate tumor cells in vivo in the absence of CD8(+) T cells. We have CD4(+) T cells specific for a MHC class II-restricted, tumor-specific peptide derived from a mutant ribosomal protein expressed by the UV light-induced tumor 6132A-PRO. By using neutralizing mAb specific for murine IFN-gamma and adoptive transfer of CD4(+) T cells into severe combined immunodeficient mice, we show that anti-IFN-gamma treatment abolishes the CD4(+) T cell-mediated rejection of the tumor cells in vivo. The tumor cells were MHC class II negative, and IFN-gamma did not induce MHC class II expression in vitro. Therefore, the tumor-specific antigenic peptide must be presented by host cells and not the tumor cells. Tumor cells transduced to secrete IFN-gamma had a markedly reduced growth rate in severe combined immunodeficient mice, but IFN-gamma did not inhibit the growth of the tumor cells in vitro. Furthermore, tumor cells stably expressing a dominant-negative truncated form of the murine IFN-gamma receptor alpha chain, and therefore insensitive to IFN-gamma, nevertheless were rejected by the adoptively transferred CD4(+) T cells. Thus, host cells, and not tumor cells, seem to be the target of IFN-gamma. Together, these results show that CD4(+) T cells can eliminate IFN-gamma-insensitive, MHC class II-negative cancer cells by an indirect mechanism that depends on IFN-gamma.     

Autologous CD4 T-cell responses to ectopic class II major histocompatibility complex antigen-expressing single-cell islet cells: an in vitro insight into the pathogenesis of lymphocytic insulitis in nonobese diabetic mice.

We investigated by flow cytometric analysis the expression of class II major histocompatibility complex (MHC) molecules by viable single-cell islet cells (SCICs) prepared from male and female 4- and 10-week-old nonobese diabetic (NOD) mouse islets. With anti-I-Ak monoclonal antibody (specific for I-Ak,f,r,s beta and produced by clone 11-5-2), and fluorescein isothiocyanate-conjugated goat anti-mouse IgG as second-step antibody, we found that SCICs from both sexes aberrantly expressed class II MHC molecules, which was not altered after SCICs were cultured for 24 hr or 120 hr in the presence of 10 ng of recombinant murine interferon gamma per ml. Double-indirect immunofluorescence of male SCICs indicated that the expression of class II MHC molecules was a property of beta cells. Control experiments documented that macrophages and mononuclear cells did not contaminate the SCIC preparations. Coculture experiments with responder splenic CD4 T cells isolated from diabetic NOD mice and stimulator male SCICs indicated a recognition event evidenced by a 12-fold increase in proliferative response. Monoclonal antibodies to class II MHC and CD4 antigens blocked the proliferative response. Results from control autologous and allogeneic mixed lymphocyte reactions suggest that the responder CD4 T cells are autoreactive self-class II MHC restricted. We tentatively conclude that the ability of SCICs from both sexes of NOD mice to express class II MHC molecules as early as 4 weeks of age may represent a mechanism for targeting immune reactions to beta cells and initiate lymphocytic insulitis.