Uveal melanoma cell-based vaccines express MHC II molecules that traffic via the endocytic and secretory pathways and activate CD8+ cytotoxic, tumor-specific T cells

We are exploring cell-based vaccines as a treatment for the 50% of patients with large primary uveal melanomas who develop lethal metastatic disease. MHC II uveal melanoma vaccines are MHC class I⁺ uveal melanoma cells transduced with CD80 genes and MHC II genes syngeneic to the recipient. Previous studies demonstrated that the vaccines activate tumor-specific CD4⁺ T cells from patients with metastatic uveal melanoma. We have hypothesized that vaccine potency is due to the absence of the MHC II-associated invariant chain (Ii). In the absence of Ii, newly synthesized MHC II molecules traffic intracellularly via a non-traditional pathway where they encounter and bind novel tumor peptides. Using confocal microscopy, we now confirm this hypothesis and demonstrate that MHC II molecules are present in both the endosomal and secretory pathways in vaccine cells. We also demonstrate that uveal melanoma MHC II vaccines activate uveal melanoma-specific, cytolytic CD8⁺ T cells that do not lyse normal fibroblasts or other tumor cells. Surprisingly, the CD8⁺ T cells are cytolytic for HLA-A syngeneic and MHC I-mismatched uveal melanomas. Collectively, these studies demonstrate that MHC II uveal melanoma vaccines are potent activators of tumor-specific CD4⁺ and CD8⁺ T cells and suggest that the non-conventional intracellular trafficking pattern of MHC II may contribute to their enhanced immunogenicity. Since MHC I compatibility is unnecessary for the activation of cytolytic CD8⁺ T cells, the vaccines could be used in uveal melanoma patients without regard to MHC I genotype.     

Regulation of MHC class I and II gene transcription: differences and similarities

Major histocompatibility complex (MHC) molecules serve as peptide receptors. These peptides are derived from processed cellular or extra-cellular antigens. The MHC gene complex encodes two major classes of molecules, MHC class I and class II, whose function is to present peptides to CD8⁺ (cytotoxic) and CD4⁺ (helper) T cells, respectively. The genes encoding both classes of MHC molecules seem to originate from a common ancestral gene. One of the hallmarks of the MHC is its extensive polymorphism which displays locus and allele-specific characteristics among the various MHC class I and class II genes. Because of its central role in immunosurveillance and in various disease states, the MHC is one of the best studied genetic systems. This review addresses several aspects of MHC class I and class II gene regulation in human and in particular, the contribution to the constitutive and cytokine-induced expression of MHC class I and II genes of MHC class-specific regulatory elements and regulatory elements which apparently are shared by the promoters of MHC class I and class II genes. Received: 12 January 1998     

HIV receptors within the brain: A study of CD4 and MHC-II on human neurons,astrocytes and microglial cells

We have investigated the level of expression of CD4 and MHC-II antigens on CNS cells and compared it to that on monocytes. MHC-II antigens were expressed spontaneously on cultured astrocytes and monocytes, whereas they were detected only after IFNγ stimulation of microglial cells. In vitro, CD4 receptor was present on monocytes but not on neurons, astrocytes or microglial cells. In normal brain, CD4 antigen was expressed on perivascular microglial cells, a specialized microglia expressing monocytic markers, whereas in HIV1-infected brain, CD4⁺ cells were numerous and scattered throughout the whole parenchyma. These CD4⁺ macrophages may be HIV1-infected monocytes which have crossed the blood-brain barrier after infection, or perivascular microglial cells infected by HIV1-infected blood lymphocytes or free virions.     

The immune system utilizes two distinct effector mechanisms of T cells depending on two different life cycle stages of a single pathogen,Toxoplasma gondii,to control its cerebral infection

Toxoplasma gondii takes two different life cycle stages within intermediate hosts including humans. Tachyzoites proliferate during the acute stage, and they transform into cysts to establish a chronic infection preferentially in the brain. IFN-γ production by infiltrated CD4⁺ and CD8⁺ T cells is required for the prevention of cerebral tachyzoite growth. IFN-γ production by brain-resident cells, most likely microglia, plays a key first line defense role to facilitate both innate and T cell-mediated protective immunity to control the tachyzoite growth. IFN-γ produced by brain-resident cells activates cerebral expression of IFN-dependent effector molecules to suppress tachyzoite growth during the early stage of infection. Their IFN-γ production also induces an expression of CXCL9 and CXCL10 chemokines to recruit immune T cells into the brain, and upregulates cerebral expression of MHC class I and II molecules for antigen presentation to the recruited T cells to activate their IFN-γ production. CD8⁺ T cells also have the activity to remove T. gondii cysts from the brains of infected hosts. Of interest, the anti-cyst activity of CD8⁺ T cells does not require their IFN-γ but does require perforin. Notably, we discovered that CD8⁺ cytotoxic T cells penetrate in the cysts in a perforin-mediated manner, which induces morphological deterioration and destruction of the cysts and an accumulation of microglia and macrophages for their elimination. Thus, the immune system employs two distinct effector mechanisms mediated by IFN-γ or perforin depending on two different life cycle stages of a single pathogen, T. gondii, to control its cerebral infection.     

Positive and negative selection of Tcrb-V6+ T cells

Tcrb-V6⁺ T cells are deleted by an endogenous superantigen probably encoded by a mouse mammary tumor provirus (Mtv), Mtv-7, in association with major histocompatibility complex (MHC) class II molecules. In contrast, Tcrb-V6⁺CD4⁺ T cells are positively selected by MHC class II E molecules in Mtv-7 ^– mice. We have examined the levels of Tcrb-V6⁺CD4⁺ and Tcrb-V6⁺CD8⁺ T cells from six combinations of backcross mice. In this paper we show that: 1) Tcrb-V6⁺CD8⁺ T cells can be positively selected by MHC class I molecules; 2) MHC class II A molecules can also influence the levels of Tcrb-V6⁺CD4⁺ T cells; 3) Mtv-7 ^– NZW mice have a new Mtv, Mtv-44, which co-segregates with a gene encoding the partial deletion ligand for Tcrb-V6⁺ T cells; 4) the remaining Tcrb-V6⁺ T cells from mice with partial deletion of these T cells appear not to be anergized in the periphery. Address correspondence and offprint requests to: K. Tomonari.     

Differential Transmembrane Domain GXXXG Motif Pairing Impacts Major Histocompatibility Complex (MHC) Class II Structure

Major histocompatibility complex (MHC) class II molecules exhibit conformational heterogeneity, which influences their ability to stimulate CD4 T cells and drive immune responses. Previous studies suggest a role for the transmembrane domain of the class II αβ heterodimer in determining molecular structure and function. Our previous studies identified an MHC class II conformer that is marked by the Ia.2 epitope. These Ia.2⁺ class II conformers are lipid raft-associated and able to drive both tyrosine kinase signaling and efficient antigen presentation to CD4 T cells. Here, we establish that the Ia.2⁺ I-A^k conformer is formed early in the class II biosynthetic pathway and that differential pairing of highly conserved transmembrane domain GXXXG dimerization motifs is responsible for formation of Ia.2⁺ versus Ia.2⁻ I-A^k class II conformers and controlling lipid raft partitioning. These findings provide a molecular explanation for the formation of two distinct MHC class II conformers that differ in their inherent ability to signal and drive robust T cell activation, providing new insight into the role of MHC class II in regulating antigen-presenting cell-T cell interactions critical to the initiation and control of multiple aspects of the immune response.     

Herpes B Virus,Macacine Herpesvirus 1, Breaks Simplex Virus Tradition via Major Histocompatibility Complex Class I Expression in Cells from Human and Macaque Hosts

B virus of the family Herpesviridae is endemic to rhesus macaques but results in 80% fatality in untreated humans who are zoonotically infected. Downregulation of major histocompatibility complex (MHC) class I in order to evade CD8⁺ T-cell activation is characteristic of most herpesviruses. Here we examined the cell surface presence and total protein expression of MHC class I molecules in B virus-infected human foreskin fibroblast cells and macaque kidney epithelial cells in culture, which are representative of foreign and natural host initial target cells of B virus. Our results show <20% downregulation of surface MHC class I molecules in either type of host cells infected with B virus, which is statistically insignificantly different from that observed in uninfected cells. We also examined the surface expression of MHC class Ib molecules, HLA-E and HLA-G, involved in NK cell inhibition. Our results showed significant upregulation of HLA-E and HLA-G in host cells infected with B virus relative to the amounts observed in other herpesvirus-infected cells. These results suggest that B virus-infected cell surfaces maintain normal levels of MHC class Ia molecules, a finding unique among simplex viruses. This is a unique divergence in immune evasion for B virus, which, unlike human simplex viruses, does not inhibit the transport of peptides for loading onto MHC class Ia molecules because B virus ICP47 lacks a transporter-associated protein binding domain. The fact that MHC class Ib molecules were significantly upregulated has additional implications for host-pathogen interactions.     

Major Histocompatibility Complex Class II+ Invariant Chain Negative Breast Cancer Cells Present Unique Peptides that Activate Tumor-specific T Cells from Breast Cancer Patients

The major histocompatibility complex (MHC) class II-associated Invariant chain (Ii) is present in professional antigen presenting cells where it regulates peptide loading onto MHC class II molecules and the peptidome presented to CD4⁺ T lymphocytes. Because Ii prevents peptide loading in neutral subcellular compartments, we reasoned that Ii⁻ cells may present peptides not presented by Ii⁺ cells. Based on the hypothesis that patients are tolerant to MHC II-restricted tumor peptides presented by Ii⁺ cells, but will not be tolerant to novel peptides presented by Ii⁻ cells, we generated MHC II vaccines to activate cancer patients'' T cells. The vaccines are Ii⁻ tumor cells expressing syngeneic HLA-DR and the costimulatory molecule CD80. We used liquid chromatography coupled with mass spectrometry to sequence MHC II-restricted peptides from Ii⁺ and Ii⁻ MCF10 human breast cancer cells transfected with HLA-DR7 or the MHC Class II transactivator CIITA to determine if Ii⁻ cells present novel peptides. Ii expression was induced in the HLA-DR7 transfectants by transfection of Ii, and inhibited in the CIITA transfectants by RNA interference. Peptides were analyzed and binding affinity predicted by artificial neural net analysis. HLA-DR7-restricted peptides from Ii⁻ and Ii⁺ cells do not differ in size or in subcellular location of their source proteins; however, a subset of HLA-DR7-restricted peptides of Ii⁻ cells are not presented by Ii⁺ cells, and are derived from source proteins not used by Ii⁺ cells. Peptides from Ii⁻ cells with the highest predicted HLA-DR7 binding affinity were synthesized, and activated tumor-specific HLA-DR7⁺ human T cells from healthy donors and breast cancer patients, demonstrating that the MS-identified peptides are bonafide tumor antigens. These results demonstrate that Ii regulates the repertoire of tumor peptides presented by MHC class II⁺ breast cancer cells and identify novel immunogenic MHC II-restricted peptides that are potential therapeutic reagents for cancer patients.Cancer vaccines are a promising tool for cancer treatment and prevention because of their potential for inducing tumor-specific responses in conjunction with minimal toxicity for healthy cells. Cancer vaccines are based on the concept that tumor cells synthesize multiple peptides that are potential immunogens, and that with the appropriate vaccine protocol, these peptides will activate an efficacious antitumor response in the patient. Much effort has been invested in identifying and testing tumor-encoded peptides, particularly peptides presented by major histocompatibility complex (MHC)¹ class I, molecules capable of activating CD8⁺ T-cells that directly kill tumor cells (1, 2). Fewer studies have been devoted to identifying MHC class II-restricted peptides for the activation of tumor-reactive CD4⁺ T-cells despite compelling evidence that Type 1 CD4⁺ T helper cells facilitate the optimal activation of CD8⁺ T-cells and the generation of immune memory, which is likely to be essential for protection from metastatic disease.Activation of CD4⁺ T cells requires delivery of a costimulatory signal plus an antigen-specific signal consisting of peptide bound to an MHC II molecule. Most cells do not express MHC II or costimulatory molecules, so CD4⁺ T cells are typically activated by professional antigen presenting cells (APC), which endocytose exogenously synthesized antigen and process and present it in the context of their own MHC II molecules. This processing and presentation process requires Invariant chain (Ii), a molecule that is coordinately synthesized with MHC II molecules and prevents the binding and presentation of APC-encoded endogenous peptides (3, 4). As a result, tumor-reactive CD4⁺ T cells are activated to tumor peptides generated by the antigen processing machinery of professional APC, rather than peptides generated by the tumor cells. Because of the potential discrepancy in peptide generation between professional APC and tumor cells, and the critical role of Ii in preventing the presentation of endogenous peptides, we have generated “MHC II cancer vaccines” that consist of Ii⁻ tumor cells transfected with syngeneic MHC class II and CD80 genes. We reasoned that MHC II⁺Ii⁻CD80⁺ tumor cells may present a novel repertoire of MHC II-restricted tumor peptides that are not presented by professional APC, and therefore may be highly immunogenic. Once activated, CD4⁺ T cells produce IFNγ and provide help to CD8⁺ T cells and do not need to react with native tumor cells. Therefore, the MHC II vaccines have the potential to activate CD4⁺ Th1 cells that facilitate antitumor immunity. In vitro (5) and in vivo (5–7) studies with mice support this conclusion. In vitro studies with human MHC II vaccines further demonstrate that the absence of Ii facilitates the activation of MHC II-restricted tumor-specific CD4⁺ type 1 T cells of HLA-DR-syngeneic healthy donors and cancer patients, and that the vaccines activate CD4⁺ T cells with a distinct repertoire of T cell receptors (8–12). A critical negative role for Ii is also supported by studies of human acute myelogenous leukemia (AML). High levels of class II-associated invariant chain peptide (CLIP), a degradation product of Ii, by leukemic blasts is associated with poor patient prognosis (13, 14), whereas down-modulation of CLIP on AML cells increases the activation of tumor-reactive human CD4⁺ T cells (14, 15).We have now used mass spectrometry to identify MHC II-restricted peptides from MHC II⁺Ii⁻ and MHC II⁺Ii⁺ human breast cancer cells to test the concept that the absence of Ii facilitates the presentation of unique immunogenic MHC II-restricted peptides. We report here that a subset of MHC II-restricted peptides from HLA-DR7⁺ breast cancer cells are unique to Ii⁻ cells and are derived from source proteins not used by Ii⁺ cells. Ii⁻ peptides have high binding affinity for HLA-DR7 and activate tumor-specific T-cells from the peripheral blood of healthy donors and breast cancer patients. This is the first study to compare the human tumor cell MHC II peptidome in the absence or presence of Ii and to demonstrate that MHC II⁺Ii⁻ tumor cells present novel immunogenic MHC II-restricted peptides that are potential therapeutic reagents for cancer patients.     

Antibodies to MHC Class II Molecules Induce Autoimmunity: Critical Role for Macrophages in the Immunopathogenesis of Obliterative Airway Disease

Previous studies have shown that intrabronchial administration of antibodies (Abs) to MHC class I resulted in development of obliterative airway disease (OAD), a correlate of chronic human lung allograft rejection. Since development of Abs specific to mismatched donor HLA class II have also been associated with chronic human lung allograft rejection, we analyzed the role of Abs to MHC class II in inducing OAD. Administration of MHC class II Abs (M5/114) to C57BL/6 mice induced the classical features of OAD even though MHC class II expression is absent de novo on murine lung epithelial and endothelial cells. The induction of OAD was accompanied by enhanced cellular and humoral immune responses to self-antigens (Collagen V and K- α1Tubulin). Further, lung-infiltrating macrophages demonstrated a switch in their phenotype predominance from MΦ1 (F4/80⁺CD11c⁺) to MΦ2 (F4/80⁺CD206⁺) following administration of Abs and prior to development of OAD. Passive administration of macrophages harvested from animals with OAD but not from naïve animals induced OAD lesions. We conclude that MHC class II Abs induces a phenotype switch of lung infiltrating macrophages from MΦ1 (F4/80⁺CD11c⁺) to MΦ2 (F4/80⁺CD206⁺) resulting in the breakdown of self-tolerance along with an increase in autoimmune Th17 response leading to OAD.     

ATGs help MHC class II,but inhibit MHC class I antigen presentation

We have recently shown that the LC3/Atg8 lipidation machinery of macroautophagy is involved in the internalization of MHC class I molecules. Decreased internalization in the absence of ATG5 or ATG7 leads to MHC class I surface stabilization on dendritic cells and macrophages, resulting in elevated CD8⁺ T cell responses during viral infections and improved immune control. Here, we discuss how the autophagic machinery supports MHC class II restricted antigen presentation, while compromising MHC class I presentation via internalization and degradation.     

Modes of Calreticulin Recruitment to the Major Histocompatibility Complex Class I Assembly Pathway

Major histocompatibility complex (MHC) class I molecules are ligands for T-cell receptors of CD8⁺ T cells and inhibitory receptors of natural killer cells. Assembly of the heavy chain, light chain, and peptide components of MHC class I molecules occurs in the endoplasmic reticulum (ER). Specific assembly factors and generic ER chaperones, collectively called the MHC class I peptide loading complex (PLC), are required for MHC class I assembly. Calreticulin has an important role within the PLC and induces MHC class I cell surface expression, but the interactions and mechanisms involved are incompletely understood. We show that interactions with the thiol oxidoreductase ERp57 and substrate glycans are important for the recruitment of calreticulin into the PLC and for its functional activities in MHC class I assembly. The glycan and ERp57 binding sites of calreticulin contribute directly or indirectly to complexes between calreticulin and the MHC class I assembly factor tapasin and are important for maintaining steady-state levels of both tapasin and MHC class I heavy chains. A number of destabilizing conditions and mutations induce generic polypeptide binding sites on calreticulin and contribute to calreticulin-mediated suppression of misfolded protein aggregation in vitro. We show that generic polypeptide binding sites per se are insufficient for stable recruitment of calreticulin to PLC substrates in cells. However, such binding sites could contribute to substrate stabilization in a step that follows the glycan and ERp57-dependent recruitment of calreticulin to the PLC.     

The absence of invariant chain in MHC II cancer vaccines enhances the activation of tumor-reactive type 1 CD4<Superscript>+</Superscript> T lymphocytes

Activation of tumor-reactive T lymphocytes is a promising approach for the prevention and treatment of patients with metastatic cancers. Strategies that activate CD8⁺ T cells are particularly promising because of the cytotoxicity and specificity of CD8⁺ T cells for tumor cells. Optimal CD8⁺ T cell activity requires the co-activation of CD4⁺ T cells, which are critical for immune memory and protection against latent metastatic disease. Therefore, we are developing “MHC II” vaccines that activate tumor-reactive CD4⁺ T cells. MHC II vaccines are MHC class I⁺ tumor cells that are transduced with costimulatory molecules and MHC II alleles syngeneic to the prospective recipient. Because the vaccine cells do not express the MHC II-associated invariant chain (Ii), we hypothesized that they will present endogenously synthesized tumor peptides that are not presented by professional Ii⁺ antigen presenting cells (APC) and will therefore overcome tolerance to activate CD4⁺ T cells. We now report that MHC II vaccines prepared from human MCF10 mammary carcinoma cells are more efficient than Ii⁺ APC for priming and boosting Type 1 CD4⁺ T cells. MHC II vaccines consistently induce greater expansion of CD4⁺ T cells which secrete more IFNγ and they activate an overlapping, but distinct repertoire of CD4⁺ T cells as measured by T cell receptor Vβ usage, compared to Ii⁺ APC. Therefore, the absence of Ii facilitates a robust CD4⁺ T cell response that includes the presentation of peptides that are presented by traditional APC, as well as peptides that are uniquely presented by the Ii⁻ vaccine cells.     

Post-Spaceflight (STS-135) Mouse Splenocytes Demonstrate Altered Activation Properties and Surface Molecule Expression

Alterations in immune function have been documented during or post-spaceflight and in ground based models of microgravity. Identification of immune parameters that are dysregulated during spaceflight is an important step in mitigating crew health risks during deep space missions. The in vitro analysis of leukocyte activity post-spaceflight in both human and animal species is primarily focused on lymphocytic function. This report completes a broader spectrum analysis of mouse lymphocyte and monocyte changes post 13 days orbital flight (mission STS-135). Analysis includes an examination in surface markers for cell activation, and antigen presentation and co-stimulatory molecules. Cytokine production was measured after stimulation with T-cell mitogen or TLR-2, TLR-4, or TLR-5 agonists. Splenocyte surface marker analysis immediate post-spaceflight and after in vitro culture demonstrated unique changes in phenotypic populations between the flight mice and matched treatment ground controls. Post-spaceflight splenocytes (flight splenocytes) had lower expression intensity of CD4⁺CD25⁺ and CD8⁺CD25⁺ cells, lower percentage of CD11c⁺MHC II⁺ cells, and higher percentage of CD11c⁺MHC I⁺ populations compared to ground controls. The flight splenocytes demonstrated an increase in phagocytic activity. Stimulation with ConA led to decrease in CD4⁺ population but increased CD4⁺CD25⁺ cells compared to ground controls. Culturing with TLR agonists led to a decrease in CD11c⁺ population in splenocytes isolated from flight mice compared to ground controls. Consequently, flight splenocytes with or without TLR-agonist stimulation showed a decrease in CD11c⁺MHC I⁺, CD11c⁺MHC II⁺, and CD11c⁺CD86⁺ cells compared to ground controls. Production of IFN-γ was decreased and IL-2 was increased from ConA stimulated flight splenocytes. This study demonstrated that expression of surface molecules can be affected by conditions of spaceflight and impaired responsiveness persists under culture conditions in vitro.     

CD4+ T cell-mediated cytotoxicity is associated with MHC class II expression on malignant CD19+ B cells in diffuse large B cell lymphoma

Diffuse large B cell lymphoma (DLBCL) is a common B cell malignancy with approximately 30% of patients present relapsed or refractory disease after first-line therapy. Research of further treatment options is needed. Cytotoxic CD4⁺ T cells express cytolytic molecules and have potential antitumor function. Here, we showed that the CD19⁺ cells from DLBCL patients presented significantly reduced expression of MHC II molecules than those from healthy controls. Three years after the first-line treatment, patients that presented relapsed disease had significantly lower MHC II expression on their CD19⁺ cells than patients who did not show recurrence. Examining cytotoxic CD4⁺ T cells show that DLBCL patients presented significantly elevated frequencies of granzyme A-, granzyme B-, and/or perforin-expressing cytotoxic CD4⁺ T cells. Also, frequency of cytotoxic CD4⁺ T cells in DLBCL patients was positively correlated with the MHC II expression level. Subsequently, the cytotoxic potential of CD4⁺ T cells against autologous CD19⁺ cells was investigated. We found that the cytotoxic potential of CD4⁺ T cells was highest in MHC II-high, intermediate in MHC II-mid, and lowest in MHC II-low patients. The percentage of MHC II-expressing viable CD19⁺ cells presented a significant reduction after longer incubation with cytotoxic CD4⁺ T cells, suggesting that cytotoxic CD4⁺ T cells preferentially eliminated MHC II-expressing CD19⁺ cells. Blocking MHC II on CD19⁺ cells significantly reduced the cytolytic capacity of CD4⁺ T cells. Despite these discoveries, the frequency of cytotoxic CD4⁺ T cells did not predict the clinical outcome of DLBCL patients. Together, these results demonstrated that cytotoxic CD4⁺ T cells presented an MHC II-dependent cytotoxic potential against autologous CD19⁺ cells and could potentially represent a future treatment option for DLBCL.     

Coreceptor function of CD4 in response to the MHC class I molecule

The specificity of the T-cell receptor (TCR) and its interaction with coreceptors play a crucial role in T-cell passing through developmental checkpoints and, eventually, determine the efficiency of adaptive immunity. The genes for the α and β chains of TCR were cloned from T-cell hybridoma 1D1, which was obtained by fusion of BWZ.36CD8α cells with CD8⁺ memory cells specific for the H-2K^b MHC class I molecule. Retroviral transduction of the 1D1 TCR genes and the CD4 and CD8 coreceptor genes was used to obtain 4G4 thymoma variants that exposed the CD3/TCR complex together with CD4, CD8, or both of the coreceptors on their surface. Although the main function of CD4 is to stabilize the interaction of TCR with MHC class II molecules, CD4 was found to mediate the activation of transfected cells via TCR specific for the H-2K^b MHC class I molecule. Moreover, CD4 proved to dominate over CD8, since the response of CD4⁺CD8⁺ transfectants was suppressed by antibodies against CD4 and the A^b MHC class II molecule but not to CD8. The response of CD4⁺ transfectants was not due to a cross-reaction of 1D1 TCR with MHC class II molecules, because the transfectants did not respond to splenocytes of H-2^b knockout mice, which were defective in the assembly of the MHC class I molecule/β2 microglobulin/peptide complex and did not expose the complex on cell surface. The domination was not due to sequestration of p56^lck kinase, since CD4 devoid of the kinase-binding site was functional in 4G4 thymoma cells. The results were used to explain some features of intrathymic cell selection and assumed to provide an experimental basis for developing new methods of anticancer gene therapy.     

Cancer immunotherapy by antisense suppression of Ii protein in MHC-class-II-positive tumor cells

This study was aimed at creating a more effective tumor cell vaccine by suppressing Ii protein in the presence of MHC class II molecules within a cancer cell. Absence of the Ii protein, which normally blocks the antigenic-peptide-binding site of MHC class II molecules at synthesis in the endoplasmic reticulum, presumably increases the range of cancer-related epitopes presented to CD4⁺ helper T cells. Effective suppression of Ii protein was achieved with an antisense, phosphorothioate oligonucleotide, which was selected on the basis of (1) the RNase H activation assay, (2) an assay for Ii protein suppression, and (3) a test for potency with respect to the extent of base sequence (“sequence walking”). The SaI murine sarcoma, which is MHC-class-I⁺ and MHC-class-II⁻, Ii-protein⁻, upon transfection with genes for either interferon γ or the MHC class II transactivator, came to express MHC class II molecules and Ii protein. In each line of transfected tumor cells, the antisense oligonucleotide profoundly suppressed Ii protein in 35%–55% cells, without affecting expression of MHC class II molecules. Inoculation of mice with such Ii-protein-suppressed tumor vaccine cells, after either formaldehyde fixation or X-irradiation, led to much greater protection against challenge with the parental SaI sarcoma than did inoculation with untreated cells. This approach to cancer cell vaccination can be applied in a wide range of human tumors. Received: 22 June 1999 / Accepted: 28 July 1999     

Dynamics of monocytes/macrophages and T lymphocytes in acutely rejecting rat renal allografts

We examined the infiltration of acutely rejecting renal allografts (DA→LEW) by ED1⁺ and ED2⁺ macrophages and T lymphocytes at intervals of 24 h after transplantation. Donor and recipient macrophages were differentiated by MHC class II antigen expression in double-staining experiments with ED1. Proliferation was assayed after pulse-labelling with BrdU. We subdivided allograft infiltration into three consecutive phases: 1) During phase I on days 1 to 2 after allogeneic kidney transplantation, perivascular infiltrates developed that contained numerous donor and recipient macrophages. Allograft rejection could already be diagnosed 24?h after transplantation by perivascular infiltration of T lymphocytes, whereas T cells were rarely found in isografts. 2) Phase II of allograft rejection from day 3 to 4 was characterized by massive propagation of the infiltrate. About equal numbers of interstitial donor and recipient macrophages were counted. Both macrophages and T lymphocytes proliferated in situ and macrophages outnumbered T cells until complete rejection. 3) During phase III the allograft was destroyed. Large intravascular monocytes surprisingly expressed the ED2 antigen. In the interstitium of viable graft regions, the population of recipient macrophages grew, whereas the population of donor macrophages and of T lymphocytes decreased.     

Application of Allogeneic Bone Marrow Cells in View of Residual Alloreactivity: Sirolimus but Not Cyclosporine Evolves Tolerogenic Properties

Background

Application of bone marrow cells (BMC) is a promising strategy for tolerance induction, but usually requires strong depletion of the host immune system. This study evaluates the ability of immunosuppressants to evolve tolerogenic properties of BMC in view of residual alloreactivity.

Methods

The rat model used a major histocompatibility complex (MHC) class II disparate bone marrow transplantation (BMT) setting (LEW.1AR1 (RT1^auu) → LEW.1AR2 (RT1^aau)). Heart grafts (LEW.1WR1 (RT1^uua)) were disparate for the complete MHC to recipients and for MHC class I to BMC donors. Limited conditioning was performed by total body irradiation of 6 Gy. Cyclosporine (CsA) or Sirolimus (Srl) were administered for 14 or 28 days. Transplantation of heart grafts (HTx) was performed at day 16 or at day 100 after BMT. Chimerism and changes in the T cell pool were detected by flow cytometry.

Results

Mixed chimeras accepted HTx indefinitely, although the composition of the regenerated T cell pool was not changed to a basically donor MHC class II haplotype. Non-chimeric animals rejected HTx spontaneously. BMC recipients, who received HTx during T cell recovery at day 16, accepted HTx only after pre-treatment with Srl, although chimerism was lost. CsA pre-treatment led to accelerated HTx rejection as did isolated application of BMC.

Conclusion

Srl evolves tolerogenic properties of allogeneic BMC to achieve indefinite acceptance of partly MHC disparate HTx despite residual alloreactivity and in particular loss of chimerism.     

Phenotypic,Ultra-Structural,and Functional Characterization of Bovine Peripheral Blood Dendritic Cell Subsets

Dendritic cells (DC) are multi-functional cells that bridge the gap between innate and adaptive immune systems. In bovine, significant information is lacking on the precise identity and role of peripheral blood DC subsets. In this study, we identify and characterize bovine peripheral blood DC subsets directly ex vivo, without further in vitro manipulation. Multi-color flow cytometric analysis revealed that three DC subsets could be identified. Bovine plasmacytoid DC were phenotypically identified by a unique pattern of cell surface protein expression including CD4, exhibited an extensive endoplasmic reticulum and Golgi apparatus, efficiently internalized and degraded exogenous antigen, and were the only peripheral blood cells specialized in the production of type I IFN following activation with Toll-like receptor (TLR) agonists. Conventional DC were identified by expression of a different pattern of cell surface proteins including CD11c, MHC class II, and CD80, among others, the display of extensive dendritic protrusions on their plasma membrane, expression of very high levels of MHC class II and co-stimulatory molecules, efficient internalization and degradation of exogenous antigen, and ready production of detectable levels of TNF-alpha in response to TLR activation. Our investigations also revealed a third novel DC subset that may be a precursor of conventional DC that were MHC class II⁺ and CD11c⁻. These cells exhibited a smooth plasma membrane with a rounded nucleus, produced TNF-alpha in response to TLR-activation (albeit lower than CD11c⁺ DC), and were the least efficient in internalization/degradation of exogenous antigen. These studies define three bovine blood DC subsets with distinct phenotypic and functional characteristics which can be analyzed during immune responses to pathogens and vaccinations of cattle.