On the development of a neoantigen vaccine for the prevention of Lynch Syndrome

Lynch Syndrome (LS) is an autosomal dominant genetic condition that causes a high risk of colorectal cancer (CRC). The hallmark of LS is genetic instability as a result of mismatch repair (MMR) deficiency, particularly in repetitive low complexity regions called microsatellites (MS). MLH1^-/- mice deficient in MMR are prone to developing tumors in the colon, upon oral administration of dextran sodium sulfate (DSS), at a rate of more than 70%. Using this LS mouse model, we found a novel tumor neo-antigen from a deletion mutation of the coding MS in the SENP6 gene that prevented tumorigenesis or hindered tumor growth rate in immunized mice. This was accomplished via high throughput exome sequencing of DSS-induced colorectal tumors in the MLH1^-/- mice and predicting the most highly immunogenic mutant gene products processed and presented as antigens in C57B6 MHC-I molecules. Throughout this study, we were able to prove the validity of the vaccine by analyzing the colorectal tumors in immunized DSS-treated mice using either our epitope, called Sp6D1, or an unrelated peptide as a negative control. Tumors developed in this context were found to be antigenic and Sp6D1-specific CD8⁺ tumor infiltrating lymphocytes (TILs) were detected by flow cytometry and cytotoxic T lymphocytes (CTL) killing assays. Additionally, immunohistochemistry showed that tumor-adjacent tertiary lymphoid organs were a potentially significant source of CD8⁺ lymphocytes. Altogether, our results indicate that there may be a protective effect to patients carrying LS mutations through the induction of a peptide-specific CTL response from the use of neoepitope vaccination. This article is protected by copyright. All rights reserved.

Avidity optimization of a MAGE-A1-specific TCR with somatic hypermutation

A T‐cell receptor (TCR) with optimal avidity to a tumor antigen can be used to redirect T cells to eradicate cancer cells via adoptive cell transfer. Cancer testis antigens (CTAs) are attractive targets because they are expressed in the testis, which is immune‐privileged, and in the tumor. However, CTAs are self‐antigens and natural TCRs to CTAs have low affinity/avidity due to central tolerance. We previously described a method of directed evolution of TCR avidity using somatic hypermutation. In this study, we made several improvements to this method and enhanced the avidity of the hT27 TCR, which is specific for the cancer testis antigen HLA‐A2‐MAGE‐A1_278‐286. We identified eight point mutations with varying degrees of improved avidity. Human T cells transduced with TCRs containing these mutations displayed enhanced tetramer binding, IFN‐γ and IL2 production, and cytotoxicity. Most of the mutations have retained specificity, except for one mutant with extremely high avidity. We demonstrate that somatic hypermutation is capable of optimizing avidity of clinically relevant TCRs for immunotherapy.

Optimizing T-cell receptor avidity with somatic hypermutation

Adoptive transfer of T cells that have been genetically modified to express an antitumor T-cell receptor (TCR) is a potent immunotherapy, but only if TCR avidity is sufficiently high. Endogenous TCRs specific to shared (self) tumor-associated antigens (TAAs) have low affinity due to central tolerance. Therefore, for effective therapy, anti-TAA TCRs with higher and optimal avidity must be generated. Here, we describe a new in vitro system for directed evolution of TCR avidity using somatic hypermutation (SHM), a mechanism used in nature by B cells for antibody optimization. We identified 44 point mutations to the Pmel-1 TCR, specific for the H-2D^b -gp100_25-33 melanoma antigen. Primary T cells transduced with TCRs containing two or three of these mutations had enhanced activity in vitro. Furthermore, the triple-mutant TCR improved in vivo therapy of tumor-bearing mice, which exhibited improved survival, smaller tumors and delayed or no relapse. TCR avidity maturation by SHM may be an effective strategy to improve cancer immunotherapy.

A universal anti-cancer vaccine: Chimeric invariant chain potentiates the inhibition of melanoma progression and the improvement of survival

For many years, clinicians and scientists attempt to develop methods to stimulate the immune system to target malignant cells. Recent data suggest that effective cancer vaccination requires combination immunotherapies to overcome tumor immune evasion. Through presentation of both MHC-I and II molecules, DCs-based vaccine platforms are effective in generating detectable CD4 and CD8 T cell responses against tumor-associated antigens. Several platforms include DC transfection with mRNA of the desired tumor antigen. These DCs are then delivered to the host and elicit an immune response against the antigen of interest. We have recently established an mRNA genetic platform which induced specific CD8⁺ cytotoxic T cell response by DC vaccination against melanoma. In our study, an MHC-II mRNA DCs vaccine platform was developed to activate CD4⁺ T cells and to enhance the anti-tumor response. The invariant chain (Ii) was modified and the semi-peptide CLIP was replaced with an MHC-II binding peptide sequences of melanoma antigens. These chimeric MHC-II constructs are presented by DCs and induce proliferation of tumor specific CD4⁺ T cells. When administered in combination with the MHC-I platform into tumor bearing mice, these constructs were able to inhibit tumor growth, and improve mouse survival. Deciphering the immunological mechanism of action, we observed an efficient CTLs killing in addition to higher levels of Th1 and Th2 subsets in the groups immunized with a combination of the MHC-I and MHC-II constructs. These universal constructs can be applied in multiple combinations and offer an attractive opportunity to improve cancer treatment.

Optimized dendritic cell vaccination induces potent CD8 T cell responses and anti-tumor effects in transgenic mouse melanoma models

Despite melanoma immunogenicity and remarkable therapeutic effects of negative immune checkpoint inhibitors, a significant fraction of patients does not respond to current treatments. This could be due to limitations in tumor immunogenicity and profound immunosuppression in the melanoma microenvironment. Moreover, insufficient tumor antigen processing and presentation by dendritic cells (DC) may hamper the development of tumor-specific T cells. Using two genetically engineered mouse melanoma models (RET and BRAF^V600E transgenic mice), in which checkpoint inhibitor therapy alone is not efficacious, we performed proof-of-concept studies with an improved, multivalent DC vaccination strategy based on our recently developed genetic mRNA cancer vaccines. The in vivo expression of multiple chimeric MHC class I receptors allows a simultaneous presentation of several melanoma-associated shared antigens tyrosinase related protein (TRP)-1, tyrosinase, human glycoprotein 100 and TRP-2. The DC vaccine induced a significantly improved survival in both transgenic mouse models. Vaccinated melanoma-bearing mice displayed an increased CD8 T cell reactivity indicated by a higher IFN-γ production and an upregulation of activation marker expression along with an attenuated immunosuppressive pattern of myeloid-derived suppressor cells (MDSC) and regulatory T cells (Treg). The combination of DC vaccination with ultra-low doses of paclitaxel or anti-PD-1 antibodies resulted in further prolongation of mouse survival associated with a stronger reduction of MDSC and Treg immunosuppressive phenotype. Our data suggest that an improved multivalent DC vaccine based on shared tumor antigens induces potent anti-tumor effects and could be combined with checkpoint inhibitors or targeting immunosuppressive cells to further improve their therapeutic efficiency.

The anti-inflammatory IFITM genes ameliorate colitis and partially protect from tumorigenesis by changing immunity and microbiota

Inflammation plays pivotal roles in different stages of tumor development. Screening for predisposing genetic abnormalities and understanding the roles these genes play in the crosstalk between immune and cancer cells will provide new targets for cancer therapy and prevention. The interferon inducible transmembrane (IFITM) genes are involved in pathogenesis of the gastro-intestinal tract. We aimed at delineating the role of IFITM3 in colonic epithelial homeostasis, inflammation and colitis-associated tumorigenesis using IFITM3-deficient mice. Chemical induction of colitis in IFITM3-deficient mice results in significantly increased clinical signs of inflammation and induction of invasive tumorigenesis. Bone marrow transplantation showed that cells of the hematopoietic system are responsible for colitis deterioration. In these mice, impaired cytokine expression skewed inflammatory response toward pathogenic Th17 with reduced expression of the anti-inflammatory cytokine IL10 during the recovery phase. Intriguingly, mice lacking the entire IFITM locus developed spontaneous chronic colitis from the age of 14 weeks. Sequencing the 16S rRNA of naïve mice lacking IFITM3 gene, or the entire locus containing five IFITM genes, revealed these mice had significant bacterial differences from their wild-type littermates. Our novel results provide strong evidence for the essential role of IFITM genes in ameliorating colitis and colitis-associated tumorigenesis.

mRNA-based dendritic cell immunization improves survival in ret transgenic mouse melanoma model

Malignant melanoma is characterized by a rapid progression, metastasis to distant organs and resistance to chemo and radiotherapy. Although melanoma is capable of eliciting an immune response, the disease progresses and the overall results of immunotherapeutic clinical studies are not satisfactory. Recently, we have developed a novel genetic platform for improving an induction of peptide-specific CD8(+) T cells by dendritic cell (DC) based on membrane-anchored β2-microglobulin (β2m) linked to a selected antigenic peptide at the N-terminus and to the cytosolic domain of TLR4 at the C-terminus. In vitro transcribed mRNA transfection of antigen-presenting cells (APCs) resulted in an efficient coupling of peptide presentation and cell activation. In this research, we utilize the chimeric platform to induce an immune response in ret transgenic mice that spontaneously develop malignant skin melanoma and to examine its effect on the overall survival of tumor-bearing mice. Following immunization with chimeric construct system, we observe a significantly prolonged survival of tumor-bearing mice as compared to the control group. Moreover, we see elevations in the frequency of CD62L(hi)CD44(hi) central and CD62L(lo)CD44(hi) effector memory CD8(+) T-cell subsets. Importantly, we do not observe any changes in frequencies of regulatory T cells (Tregs) and myeloid-derived suppressor cells (MDSCs) in the vaccinated groups. Our data suggest that this novel vaccination approach could be efficiently applied for the immunotherapy of malignant melanoma.

mRNA-transfected Dendritic Cells Expressing Polypeptides That Link MHC-I Presentation to Constitutive TLR4 Activation Confer Tumor Immunity

Recently, we have developed a novel genetic platform for improving dendritic cell (DC) induction of peptide-specific CD8 T cells, based on membrane-anchored β2-microglobulin (β2m) linked to a selected antigenic peptide at its N-terminus and to the cytosolic domain of toll-like receptor (TLR)4 C-terminally. In vitro transcribed mRNA transfection of antigen presenting cells resulted in polypeptides that efficiently coupled peptide presentation to cellular activation. In the present study, we evaluated the immunogenicity of such constructs in mRNA-transfected immature murine bone marrow-derived DCs. We show that the encoded peptide β2m-TLR4 products were expressed at the cell surface up to 72 hours and stimulated the maturation of DCs. In vivo, these DCs prompted efficient peptide-specific T-cell activation and target cell killing which were superior to those induced by peptide-loaded, LPS-stimulated DCs. This superiority was also evident in the ability to protect mice from tumor progression following the administration of B16F10.9 melanoma cells and to inhibit the development of pre-established B16F10.9 tumors. Our results provide evidence that the products of two recombinant genes encoding for peptide-hβ2m-TLR4 and peptide-hβ2m-K(b) expressed from exogenous mRNA can cooperate to couple Major Histocompatibility Complex (MHC-I) peptide presentation to TLR-mediated signaling, offering a safe, economical and highly versatile genetic platform for a novel category of CTL-inducing vaccines.

Cryoimmunotherapy with local co-administration of ex vivo generated dendritic cells and CpG-ODN immune adjuvant, elicits a specific antitumor immunity

Cryoablation is a low-invasive surgical procedure for management of malignant tumors. Tissue destruction is obtained by repeated deep freezing and thawing and results in coagulative necrosis and in apoptosis. This procedure induces the release of tumor-associated antigens and proinflammatory factors into the microenvironment. Local administration of immature dendritic cells (DCs) potentiates the immune response induced by cryoablation. To further augment the induction of long-lasting antitumor immunity, we investigated the clinical value of combining cryoimmunotherapy consisting of cryoablation and inoculation of immature DCs with administration of the immune adjuvant, CpG oligodeoxynucleotides. Injection of the murine Lewis lung carcinoma, D122-luc-5.5 that expresses the luciferase gene, results in spontaneous metastases, which can be easily monitored in vivo. The local tumor was treated by the combined treatment. The clinical outcome was assessed by monitoring tumor growth, metastasis in distant organs, overall survival, and protection from tumor recurrence. The nature of the induced T cell responses was analyzed. Combined cryoimmunotherapy results in reduced tumor growth, low metastasis and significantly prolonged survival. Moreover, this treatment induces antitumor memory that protected mice from rechallenge. The underlying suggested mechanisms are the generation of tumor-specific type 1 T cell responses, subsequent induction of cytotoxic T lymphocytes, and generation of systemic memory. Our data highlight the combined cryoimmunotherapy as a novel antitumor vaccine with promising preclinical results. Adjustment of this technique into practice will provide the therapeutic benefits of both, ablation of the primary tumor and induction of robust antitumor and antimetastatic immunity.

Production of LacZ inducible T cell hybridoma specific for human and mouse gp100₂₅₋₃₃ peptides

Identification and quantification of immunogenic peptides and tumor-derived epitopes presented on MHC-I molecules are essential for basic studies and vaccines generation. Although lymphocytes derived from transgenic mice can serve as sensitive detectors of processes of antigen presentation and recognition, they are not always available. The use of cell lines might be extremely useful. In this study, we generated a lacZ inducible CD8⁺ hybridoma (BUSA14) capable of recognizing both human and mouse gp100₂₅₋₃₃ melanoma antigens presented on dendritic and tumor cell lines. This hybridoma expresses a variety of membranal T cell markers and secretes IL-2 and TNFα. Thus, BUSA14 offers a quantifiable, cheap and straightforward tool for studying peptide presentation by MHC-I molecules on the cell surface.

Coupling presentation of MHC class I peptides to constitutive activation of antigen-presenting cells through the product of a single gene

Priming of naive CD8 T cells by dendritic cells (DCs) entails both effective antigen presentation on MHC class I products and co-stimulatory signaling. Their optimal coupling is a major goal in the development of CTL-inducing vaccines. We recently reported that a membranal derivative of the invariant MHC-I light chain, β(2)-microglobulin (β(2)m), markedly stabilizes MHC-I molecules and can serve as a universal platform for exceptional presentation of genetically linked peptides. To test whether it is possible to equip the resulting MHC-I complexes with an inherent ability to activate antigen-presenting cells, we engrafted the intracellular Toll/IL-1 receptor domain of mouse Toll-like receptor (TLR) 4 or TLR2 onto the peptide-β(2)m scaffold. We evaluated the level of peptide presentation and status of cell activation conferred by such constructs in stably transfected mouse RAW264.7 macrophages and mRNA-transfected mouse DC2.4 DCs. We show that the encoded peptide-β(2)m-TLR polypeptides are expressed at the cell surface, pair with endogenous heavy chains, stabilize MHC-I products, prompt efficient peptide-specific T-cell recognition and confer a constitutively activated phenotype on the transfected cells, as judged by the up-regulation of pro-inflammatory genes and surface co-stimulatory molecules. Our results provide evidence that the product of a single recombinant gene can couple MHC peptide presentation to TLR-mediated signaling and offer a safe, economical and highly versatile modality for a novel category of genetic CTL-inducing vaccines.

The human 1-8D gene (IFITM2) is a novel p53 independent pro-apoptotic gene

The human 1-8 interferon inducible gene family consists of at least 3 functional genes; 9-27, 1-8D and 1-8U, which are all linked on an 18-kb fragment of chromosome 11 and are highly homologous. It has recently been shown by us and others that the 1-8D gene is overexpressed in colon carcinoma. Here, we show, by sequence comparison of the 1-8D in pairs of tumor/normal colon tissues, the existence of 6 different alleles, containing single-nucleotide polymorphisms with no mutations. Transformation assays revealed a possible role for the 1-8D gene as a transformation inhibitor. Further, transient expression of the human 1-8D gene in multiple mammalian cell lines showed accumulation of cells in the G1 phase followed by elevation in the subG1 phase. SubG1 elevation was confirmed as apoptosis by Annexin-V binding assays and transferase-mediated dUTP nick end labeling assays. Moreover, knock-down of 1-8D provided partial protection from Etoposide and UV-induced apoptosis. The induction of apoptosis by 1-8D is dependent on caspase activities but not on p53 expression. Although 1-8D induces apoptosis independently of p53, p53 expression downregulates 1-8D protein expression. Our data suggest a role for the 1-8D gene as a novel pro-apoptotic gene that will provide new insights into the regulated cellular pathways to death.

Exuberated numbers of tumor-specific T cells result in tumor escape

Cytotoxic T cells (CTL) play a major role in tumor rejection. Expansion of CTLs, either by immunization or adoptive transfer, is a prominent goal in current immunotherapy. The antigen-specific nature of these expansion processes inevitably initiates a clonotypic attack on the tumor. By injecting an Ovalbumin-expressing melanoma into OT-I mice, in which >90% of CTLs recognize an Ovalbumin peptide, we show that an increased number of tumor-specific CTLs causes emergence of escape variants. We show that these escape variants are a result of antigen silencing via a yet undetermined epigenetic mechanism, which occurs frequently and is spontaneously reversible. We further show that an increase in the time of tumor onset in OT-I compared with C57BL/6J is a result of immune selection.

Preventive and therapeutic vaccination with PAP-3, a novel human prostate cancer peptide, inhibits carcinoma development in HLA transgenic mice

Conventional treatment of recurrent and metastasized prostate cancer (CaP) remains inadequate; this fact mandates development of alternative therapeutic modalities, such as specific active or passive immunotherapy. Previously, we reported the identification of a novel highly immunogenic HLA-A*0201-restricted Prostatic Acid Phosphatase-derived peptide (PAP-3) by a two-step in vivo screening in an HLA-transgenic (HHD) mouse system. In the present study we aimed at elucidating the efficiency of PAP-3-based vaccine upon active antitumor immunization. To this end we established preventive and therapeutic carcinoma models in HHD mice. The 3LL murine Lewis lung carcinoma clone D122 transduced to express HLA-A*0201 and PAP served as a platform for these models. The HLA-A*0201-PAP-3 complex specific recombinant single chain scFV-PAP-3 antibodies were generated and used to confirm an endogenous PAP processing resulting in PAP-3 presentation by HLA-A*0201. PAP-3 based vaccines significantly decreased tumor incidence in a preventive immunization setting. Therapeutic vaccination of HHD mice with PAP-3 led to rejection of early established tumors and to increase of mouse survival. These results strongly support a therapeutic relevance of the identified CTL epitope upon active antitumor immunization. The newly established carcinoma model presented herein might be a useful tool for cancer vaccine design and optimization.

Induction of antitumor immunity by CTL epitopes genetically linked to membrane-anchored beta2-microglobulin

Level and persistence of antigenic peptides presented by APCs on MHC class I (MHC-I) molecules influence the magnitude and quality of the ensuing CTL response. We recently demonstrated the unique immunological properties conferred on APCs by expressing beta2-microglobulin (beta2m) as an integral membrane protein. In this study, we explored membrane-anchored beta2m as a platform for cancer vaccines using as a model MO5, an OVA-expressing mouse B16 melanoma. We expressed in mouse RMA-S cells two H-2Kb binding peptides from MO5, OVA257-264, and TRP-2181-188, each genetically fused with the N terminus of membranal beta2m via a short linker. Specific Ab staining and T cell hybridoma activation confirmed that OVA257-264 was properly situated in the MHC-I binding groove. In vivo, transfectants expressing both peptides elicited stronger CTLs and conferred better protection against MO5 than peptide-saturated RMA-S cells. Cells expressing OVA257-264/beta2m were significantly superior to OVA257-264-charged cells in their ability to inhibit the growth of pre-established MO5 tumors. Our results highlight the immunotherapeutic potential of membranal beta2m as a universal scaffold for optimizing Ag presentation by MHC-I molecules.

O-glycosylated versus non-glycosylated MUC1-derived peptides as potential targets for cytotoxic immunotherapy of carcinoma

Due to the fact that many cellular proteins are extensively glycosylated, processing and presentation mechanisms are expected to produce a pool of major histocompatibility complex (MHC) class I-bound protein-derived peptides, part of which retain sugar moieties. The immunogenic properties of the presented glycosylated peptides in comparison to their non-glycosylated counterparts have not been determined clearly. We assessed the cellular immunogenicity of MUC1 (mucin)-derived peptides O-glycosylated with a Tn epitope (GalNAc) using HLA-A*0201 single chain (HHD)-transfected cell lines and transgenic mice. For part of the compounds Tn moiety did not interfere with the HLA-A*0201 binding. Moreover, part of the glycopeptides elicited effective cytotoxic responses, indicating recognition of the glycopeptide-HLA-A*0201 complex by the T cell receptor (TCR) and subsequent cytotoxic T lymphocyte (CTL) activation. The CTLs exhibited a substantial degree of cross-reactivity against target cells loaded with glycosylated and non-glycosylated forms of the same peptide. The studied (glyco)peptides showed cellular immunogenicity in both MUC1-HHD and HHD mice and induced effective lysis of (glyco)peptide-loaded target cells in CTL assays. However, the elicited CTLs did not induce selective lysis of human MUC1-expressing murine cell lines. Moreover, immunization with (glyco)peptide-loaded dendritic cells (DCs) did not induce significant immunotherapeutic effects. We conclude that Tn glycosylated MUC1-derived peptides can be presented by MHC class I molecules, and may be recognized by specific TCR molecules resulting in cytotoxic immune responses. However, the studied glycopeptides did not offer significant benefit as targets for cytotoxic immune response due apparently to (a) cross-reactivity of the elicited CTLs against the glycosylated and non-glycosylated forms of the same peptide and (b) low abundance of glycopeptides on tumour target cells.

Combined dendritic cell cryotherapy of tumor induces systemic antimetastatic immunity

PURPOSE

Cryotherapy of localized prostate, renal, and hepatic primary tumors and metastases is considered a minimally invasive treatment demonstrating a low complication rate in comparison with conventional surgery. The main drawback of cryotherapy is that it has no systemic effect on distant metastases. We investigated whether intratumoral injections of dendritic cells following cryotherapy of local tumors (cryoimmunotherapy) provides an improved approach to cancer treatment, combining local tumor destruction and systemic anticancer immunity.

EXPERIMENTAL DESIGNS

The 3LL murine Lewis lung carcinoma clone D122 and the ovalbumin-transfected B16 melanoma clone MO5 served as models for spontaneous metastasis. The antimetastatic effect of cryoimmunotherapy was assessed in the lung carcinoma model by monitoring mouse survival, lung weight, and induction of tumor-specific CTLs. The mechanism of cryoimmunotherapy was elucidated in the melanoma model using adoptive transfer of T cell receptor transgenic OT-I CTLs into the tumor-bearing mice, and analysis of Th1/Th2 responses by intracellular cytokine staining in CD4 and CD8 cells.

RESULTS

Cryoimmunotherapy caused robust and tumor-specific CTL responses, increased Th1 responses, significantly prolonged survival and dramatically reduced lung metastasis. Although intratumor administration of dendritic cells alone increased the proliferation rate of CD8 cells, only cryoimmunotherapy resulted in the generation of effector memory cells. Furthermore, cryoimmunotherapyprotected mice that had survived primary MO5 tumors from rechallenge with parental tumors.

CONCLUSIONS

These results present cryoimmunotherapy as a novel approach for systemic treatment of cancer. We envisage that cryotherapy of tumors combined with subsequent in situ immunotherapy by autologous unmodified immature dendritic cells can be applied in practice.

Human CTL Epitopes Prostatic Acid Phosphatase-3 and Six-Transmembrane Epithelial Antigen of Prostate-3 as Candidates for Prostate Cancer Immunotherapy

Specific immunotherapy of prostate cancer may be an alternative or be complementary to other approaches for treatment of recurrent or metastasized disease. This study aims at identifying and characterizing prostate cancer-associated peptides capable of eliciting specific CTL responses in vivo. Evaluation of peptide-induced CTL activity in vitro was done following immunization of HLA-A2 transgenic (HHD) mice. An in vivo tumor rejection was tested by adoptive transfer of HHD immune lymphocytes to nude mice bearing human tumors. To confirm the existence of peptide-specific CTL precursors in human, lymphocytes from healthy and prostate cancer individuals were stimulated in vitro in the presence of these peptides and CTL activities were assayed. Two novel immunogenic peptides derived from overexpressed prostate antigens, prostatic acid phosphatase (PAP) and six-transmembrane epithelial antigen of prostate (STEAP), were identified; these peptides were designated PAP-3 and STEAP-3. Peptide-specific CTLs lysed HLA-A2.1+ LNCaP cells and inhibited tumor growth on adoptive immunotherapy. Furthermore, peptide-primed human lymphocytes derived from healthy and prostate cancer individuals lysed peptide-pulsed T2 cells and HLA-A2.1+ LNCaP cells. Based on the results presented herein, PAP-3 and STEAP-3 are naturally processed CTL epitopes possessing anti-prostate cancer reactivity in vivo and therefore may constitute vaccine candidates to be investigated in clinical trials.

Tuftsin-AZT conjugate: potential macrophage targeting for AIDS therapy

The IgG-derived immunomodulating peptide tuftsin, Thr-Lys-Pro-Arg, is recognized by specific receptors on phagocytic cells, notably macrophages, and is capable of targeting proteins and peptides to these sites. Aiming to target 3'-azido-3'-deoxythymidine (AZT) to HIV-infected macrophages, a conjugate of AZT with tuftsin was synthesized. The AZT-tuftsin chimera possesses the characteristic capacities of its two components. Thus, like AZT, it inhibits reverse transcriptase activity and HIV-antigen expression, and similarly to tuftsin, it stimulates IL-1 release from mouse macrophages and augments the immunogenic function of the cells. Importantly, the conjugate is not cytotoxic to T-cells. The results suggest that the AZT-tuftsin conjugate might have potential use in AIDS therapy.

Membrane-anchored beta 2-microglobulin stabilizes a highly receptive state of MHC class I molecules

The magnitude of response elicited by CTL-inducing vaccines correlates with the density of MHC class I (MHC-I)-peptide complexes formed on the APC membrane. The MHC-I L chain, beta2-microglobulin (beta2m), governs complex stability. We reasoned that genetically converting beta2m into an integral membrane protein should exert a marked stabilizing effect on the resulting MHC-I molecules and enhance vaccine efficacy. In the present study, we show that expression of membranal human beta2m (hbeta2m) in mouse RMA-S cells elevates MHC-I thermal stability. RMA-S transfectants bind an exogenous peptide at concentrations 10(4)- to 10(6)-fold lower than parental RMA-S, as detected by complex-specific Abs and by T cell activation. Moreover, saturation of the transfectants' MHC-I by exogenous peptide occurs within 1 min, as compared with approximately 1 h required for parental cells. At saturation, however, level of peptide bound by modified cells is only 3- to 5-fold higher. Expression of native hbeta2m only results in marginal effect on the binding profile. Soluble beta2m has no effect on the accelerated kinetics, but the kinetics of transfectants parallel that of parental cells in the presence of Abs to hbeta2m. Ab inhibition and coimmunoprecipitation analyses suggest that both prolonged persistence of peptide-receptive H chain/beta2m heterodimers and fast heterodimer formation via lateral diffusion may contribute to stabilization. In vivo, peptide-loaded transfectants are considerably superior to parental cells in suppressing tumor growth. Our findings support the role of an allosteric mechanism in determining ternary MHC-I complex stability and propose membranal beta2m as a novel scaffold for CTL induction.

Membrane-anchored beta 2-microglobulin stabilizes a highly receptive state of MHC class I molecules

The magnitude of response elicited by CTL-inducing vaccines correlates with the density of MHC class I (MHC-I)-peptide complexes formed on the APC membrane. The MHC-I L chain, beta2-microglobulin (beta2m), governs complex stability. We reasoned that genetically converting beta2m into an integral membrane protein should exert a marked stabilizing effect on the resulting MHC-I molecules and enhance vaccine efficacy. In the present study, we show that expression of membranal human beta2m (hbeta2m) in mouse RMA-S cells elevates MHC-I thermal stability. RMA-S transfectants bind an exogenous peptide at concentrations 10(4)- to 10(6)-fold lower than parental RMA-S, as detected by complex-specific Abs and by T cell activation. Moreover, saturation of the transfectants' MHC-I by exogenous peptide occurs within 1 min, as compared with approximately 1 h required for parental cells. At saturation, however, level of peptide bound by modified cells is only 3- to 5-fold higher. Expression of native hbeta2m only results in marginal effect on the binding profile. Soluble beta2m has no effect on the accelerated kinetics, but the kinetics of transfectants parallel that of parental cells in the presence of Abs to hbeta2m. Ab inhibition and coimmunoprecipitation analyses suggest that both prolonged persistence of peptide-receptive H chain/beta2m heterodimers and fast heterodimer formation via lateral diffusion may contribute to stabilization. In vivo, peptide-loaded transfectants are considerably superior to parental cells in suppressing tumor growth. Our findings support the role of an allosteric mechanism in determining ternary MHC-I complex stability and propose membranal beta2m as a novel scaffold for CTL induction.

Expression of FasL by tumor cells does not abrogate anti-tumor CTL function

The effects of Fas-ligand (FasL) expression by tumor cells on their tumorigenicity and immunogenicity have been reported as opposite, contradictory results. In some systems the killing of Fas positive cytotoxic T-cells (CTL) by FasL expressing tumors resulted in increased tumorigenicity while in other systems tumors expressing FasL were eliminated by neutrophil mediated inflammation. In the present study, we investigated how FasL expression influences the low immunogenic Lewis lung carcinoma clone D122 and its highly immunogenic MHC I (H-2Kb) and B7-1 (CD80) transfectant 39.5-B7, by transfecting the human FasL (FasL) gene into these cells. Despite the fact that FasL-expressing cells kill effectively appropriate target cells (L1210-fas) compared to parental cells (D122) and low expressors (DFasL-33), these tumor cells were completely rejected in syngeneic mice (C57BL/6), but not in Fas mutant B6-MRL mice, suggesting that functional Fas receptor expression in the host was required to induce an anti-tumor mechanism. In addition, although FasL-expressing immunogenic tumor cells (39.5-B7-FasL 7) kill effectively target cells in vitro, both the transfectant and the mock transfectant (39.5-B7-pBabe) were rejected in syngenic mice. The sensitivity of FasL expressing tumor cells to lysis by CTLs was similar to that of FasL non-expressors. Therefore, these results indicate that FasL expression on immunogenic tumor cells does not affect their immunogenicity in vivo, as well as CTL functions in vitro.

In vivo rejection of tumor cells dependent on CD8 cells that kill independently of perforin and FasL

Perforin/granzyme B- and Fas/FasL-mediated killing pathways are the main effector mechanisms of CTL and NK cells in antitumor immune responses. In this study, we investigated the relative role of these two lytic mechanisms in protection of the host from tumor progression, as well as spontaneous metastasis, using the D122 Lewis lung carcinoma and its gene-modified cells. Utilizing perforin knockout mice (B6-PKO) and Fas and FasL mutant (B6-MRL and B6-Smn) mice, we found that perforin expression in the host plays a crucial function in the prevention of metastasis. However, local tumor rejection of an H-2K(b) and B7-1 transfectant, 39.5-B7 cells, was not dependent either on perforin or Fas/FasL expression in vivo. In addition, CTL lysis of 39.5-B7 cells was independent of perforin and Fas/FasL interactions in 18-hour in vitro assays. We also confirmed that CD8 T-cells were responsible for rejecting 39.5-B7 local tumors, yet cytokines, TNF-alpha and gammaIFN were not involved in tumor rejection in vivo. Furthermore, blocking assays using caspase inhibitors (zVAD-fmk, zLETD-fmk and zLEHD-fmk) showed that, whereas caspase activation was partially required to induce 39.5-B7 lysis mediated by the perforin-dependent pathway, 39.5-B7 lysis by CTLs through the perforin-independent mechanism required caspase activation. Thus, these results suggested that perforin, Fas/FasL, gammaIFN and TNF-alpha independent lytic mechanisms, mediated by CD8 T cells, have a crucial role in rejection of 39.5-B7 cells in vivo. Caspase activation is a pre requisite for apoptosis of targets by CTLs.

MAGE-A8 overexpression in transitional cell carcinoma of the bladder: identification of two tumour-associated antigen peptides

Bladder carcinoma is the fourth most common cancer in men and the eighth most common cancer among women. Our study is aimed to characterise tumour-associated antigen peptides of transitional cell carcinoma of the bladder (TCC). A DNA micro-array-based differential display analysis of 10 000 genes was carried out, and MAGE-A8 gene expression was detected in the tumour, and not in the normal bladder. High occurrence of MAGE-A8 expression was observed in fresh tumour samples (17 out of 23) and TCC lines (four of eight). The MAGE-A8 protein sequence was screened for HLA-A2.1-binding motifs, six potential peptides were synthesised, and peptides binding to HLA-A2.1 were assured. Immunogenicity and antigenicity of the MAGE-A8 peptides were examined in the HHD system, murine class I MHC knockout mice, transgenic for HLA-A2.1. The MAGE-A8 peptide immunogenicity was examined in three modes of vaccination, delivered intranasally with cholera toxin, injected into the tail base with complete Freund's adjuvant (CFA), or presented directly as loaded onto cell surface HLA-A2.1 molecules. Two peptides, 8.1 and 8.3, induce CTL that kills the T24 TCC line in vitro, and prime human lymphocyte response of healthy donors. These results demonstrate the potential use of the MAGE-A8 peptides for specific immunotherapy of TCC.

Characterization of novel breast carcinoma-associated BA46-derived peptides in HLA-A2.1/D(b)-beta2m transgenic mice

The human milk fat globule membrane protein BA46 (lactadherin) is highly overexpressed in human breast tumors, making it a potential target for tumor immunotherapy. We have identified BA46-derived peptides that contain the motif recognized by the MHC class I molecule HLA-A2.1 and that are processed and presented by human breast carcinoma cells. In mice lacking normal class I molecules but expressing an HLA-A2.1/D(b)-beta2 microglobulin single chain (HHD mice), three peptides elicited specific CTL activity. Two of these peptides also stimulated cytotoxic activity in peripheral blood lymphocytes from HLA-A2.1-positive breast carcinoma patients. Adoptive transfer of HHD-derived bulk CTLs to nude mice bearing human breast carcinoma transplants reduced tumor growth. These peptides therefore represent naturally processed BA46-derived CTL epitopes that can be used in peptide-based antitumor vaccines.

Analysis of endogenous peptides bound by soluble MHC class I molecules: a novel approach for identifying tumor-specific antigens

The Human MHC Project aims at comprehensive cataloging of peptides presented within the context of different human leukocyte antigens (HLA) expressed by cells of various tissue origins, both in health and in disease. Of major interest are peptides presented on cancer cells, which include peptides derived from tumor antigens that are of interest for immunotherapy. Here, HLA-restricted tumor-specific antigens were identified by transfecting human breast, ovarian and prostate tumor cell lines with truncated genes of HLA-A2 and HLA-B7. Soluble HLA secreted by these cell lines were purified by affinity chromatography and analyzed by nano-capillary electrospray ionization-tandem mass spectrometry. Typically, a large peptide pool was recovered and sequenced including peptides derived from MAGE-B2 and mucin and other new tumor-derived antigens that may serve as potential candidates for immunotherapy.

Antigenicity and immunogenicity of an intracellular delivery system of major histocompatibility complex class I epitopes that bypasses proteasome processing

The development of a cell-free synthetic vaccine to induce an effective cytotoxic T lymphocyte response is an important challenge in T-cell--mediated immunity. Because standard vaccinations with nominal epitopes were found to be only partially effective in vivo, the authors suggest an alternative strategy: the delivery of epitopes directly to the cell cytosol in a proteasome bypass mechanism of processing. Two model peptides, the presentation level on the cell surface of which can be directly assessed, were conjugated via a cross-linker to an internalization peptide derived from an antennapedia homeobox protein. The linker was designed to undergo spontaneous hydrolysis, after which the epitope is subsequently released. The conjugates were shown to enter RMA and P815 cells, where the epitopes were released mainly in cytosol and endogenously loaded on the major histocompatibility complex class I molecules to be presented on the cell surface. Concomitant inhibition of proteasome activity by MG132 significantly increased the presentation level of both model peptides, indicating proteasome-independent processing. This phenomenon was exploited to enhance the immunogenicity of the conjugates. Conjugates were emulsified with MG132 in incomplete Freund's adjuvant and injected into mouse footpads. Analysis of the draining lymph nodes indicated an increase in the percentage of both CD4+ and CD8+ lymphocytes. In vitro cytolytic assays implied significant, albeit moderate, priming only when the proteasome inhibitor was administered with the conjugate. This approach may be useful for the development of efficient synthetic cell-free vaccines.

Anti-tumor vaccination in heterozygous congenic F1 mice: presentation of tumor-associated antigen by the two parental class I alleles

Peptide vaccination of homozygous mice against syngeneic tumors using single major histocompatibility complex (MHC) class I-restricted cytotoxic T lymphocyte (CTL) epitopes elicits effective immune responses against metastatic growth. So far, single-peptide vaccination of patients against their autologous tumors seems to elicit less satisfactory results. In this study, the authors tried to determine whether effective anti-metastatic immunity requires the presentation of peptides restricted by the two parental class I major histocompatibility complex alleles in heterozygous hosts. The immune response against the H-2b-derived 3LL Lewis lung carcinoma was evaluated in heterozygous recombinant congenic F1 mice (Kk x K(b)) and (Kd x K(b)). Vaccination of such heterozygous animals with dendritic cells expressing the two parental H-2K alleles, pulsed with total tumor extract, elicited a potent anti-metastatic response. A comparable response was obtained after vaccination with tumor cells genetically modified to express the two class I alleles. In contrast, vaccination of the heterozygous mice with dendritic cells expressing only one of the parental F1 H-2K alleles or with tumors expressing only one H-2K allele failed to elicit effective immunity against tumor metastasis in recombinant congenic F1 mice. It appears, therefore, that to achieve effective anti-metastatic immunotherapy in heterozygous organisms, presentation of cytotoxic T lymphocyte epitopes restricted by the two parental class I alleles is required.

Novel breast-tumor-associated MUC1-derived peptides: characterization in Db-/- x beta2 microglobulin (beta2m) null mice transgenic for a chimeric HLA-A2.1/Db-beta2 microglobulin single chain

The MUC1 protein was found to be up-regulated in a spectrum of malignant tumors. T-cell responses to the MUC1 extracellular tandem repeat array (TRA) were observed in murine models as well as in breast-carcinoma patients. In the present study, we evaluated the anti-tumor potential of HLA-A2.1-motif-selected peptides from non-TRA domains of the molecule. Peptide immunogenicity was examined in the Db-/- x beta2 microglobulin (beta2m) null mice transgenic for a modified HLA-A2.1/Db-beta2 microglobulin single chain (HHD mice). Our results show the existence of 3 novel HLA-A2.1-restricted MUC1-derived cytotoxic T-lymphocyte (CTL) epitopes. These peptides are processed and presented by the HHD-transfected breast-tumor cell line MDA-MB-157. Moreover, CTL induced by these 3 peptides show higher lysis of target cells pulsed with breast-carcinoma-derived peptides than of targets pulsed with normal breast-tissue-derived peptides. These data suggest an important role for non-TRA MUC1-derived peptides as inducers of a MHC-restricted CTL reaction to a breast-carcinoma cell line and patient-derived tumor extracts.

Induction of antitumor immunity by proteasome-inhibited syngeneic fibroblasts pulsed with a modified TAA peptide

CTLs specific for tumor antigens play a major role in immunity against cancer. Improved binding affinity of putative TAA peptides could enhance the in vivo immunogenicity of these self-altered self- tumor antigens. We examined here the efficacy of tumor vaccines composed of an altered peptide ligand of MUT-1, designated MUT-D, which exhibited significantly higher class-I allele K(b) binding affinity than its native counterpart MUT-1. The peptide was loaded on antigen presenting cells composed of the C57BL/6-syngeneic fibroblast cell line BLK.CL4. These cells were treated with proteasome inhibitor in order to shut off the degradation of proteins and the subsequent loading of endogenous peptides onto MHC class-I molecules, thus allowing for the pulsing of these cells with the modified peptide MUT-D. Proteasome-inhibited and modified peptide-loaded fibroblasts induced a peptide-specific CTL that significantly delayed primary tumor progression and protected the pre-immunized mice against the development of lung metastasis following the surgical removal of the primary tumor. Genetic modification of the fibroblasts to express the immunostimulatory cytokine IL-2 did not improve the APC function of the modified cells, nor did it result in augmentation of the potency of the vaccine. Our results suggest that the proteasome-inhibited fibroblasts pulsed with modified, high binder tumor-associated antigen peptide are good antigen-presenting cells and represent an effective form of tumor vaccine.

Induction of antitumor immunity with modified autologous cells expressing membrane-bound murine cytokines

Development of cytokine gene-modified autologous tumor vaccines must take into account the strictly paracrine physiology of cytokines whose expression at the tumor microenvironment is important for the successful induction of tumor-specific immunity. In this study, we investigated the efficacy of a tumor vaccine composed of inactivated autologous cells transfected with two plasmid vectors encoding a mutant membrane-bound murine granulocyte-macrophage colony-stimulating factor (MuGM-CSF) and murine interferon-gamma (MuIFN-gamma). Expression of both cytokines as cell surface ligands on the highly metastatic D122 clone of Lewis lung carcinoma led to abrogation of their tumorigenicity and metastatic phenotype. More importantly, vaccination with irradiated tumor cells expressing the membrane-bound GM-CSF and IFN-gamma induced a cytotoxic T lymphocyte (CTL) response that protected syngeneic mice against a subsequent challenge with D122 cells as a primary tumor in preimmunized mice as well as against lung metastasis developing after surgical removal of the primary tumor in naive mice. Autologous cells expressing the membrane-bound GM-CSF and IFN-gamma exhibited comparable efficacy as an antimetastatic vaccine to a vaccine composed of transfectants expressing wild-type secreted cytokine molecules. These results indicate that membrane-bound cytokines can cause enhanced immunogenicity when transfected into tumor cells for the induction of antitumor immunity.

Antimetastatic vaccination against Lewis lung carcinoma with autologous tumor cells modified to express murine interleukin 12

Interleukin 12 (IL-12) is a disulfide-linked heterodimer molecule produced predominantly by professional antigen presenting cells. It promotes the induction of sundry biological effects with significant relevance to antitumor immunity, such as enhancing a T(H)1 helper response, an in vivo antiangiogenic effect, induction of adhesion molecules that assist in lymphocyte homing to sites of tumor growth, and a direct stimulatory effect on both T-cells and NK cells. We tested the efficacy of an antimetastatic vaccine composed of autologous murine D122 cells transfected with both subunits of IL-12 cDNA to express biologically-active IL-12 molecule. Expression of IL-12 by D122 cells significantly reduced their tumorigenicity and metastatic potential in immunocompetent syngeneic hosts. Furthermore, vaccination of mice with 2 x 10(6) irradiated IL-12-transfected D122 cells engendered a protective CTL response which rejected a subsequent challenge with parental D122 cells and eradicated lung micrometastasis in animals whose primary tumors have been surgically removed. The antitumor effects of IL-12 were mediated primarily by its ability to induce gammaIFN expression in vivo. CD8+ T-cells as well as NK cells were crucial in the execution of the antitumor effects of IL-12. These results suggest that autologous tumor cells expressing IL-12 by gene transfer are a potent antitumor vaccine able to induce a systemic immune response against poorly immunogenic and spontaneously metastatic tumors.

Tuftsin-THF-gamma 2 chimeric peptides: potential novel immunomodulators

Synthesis of two chimeric peptides composed of tuftsin and thymic humoral factor-gamma 2 (THF-gamma 2) conjugates was accomplished. Our goal was the generation of novel immunomodulators. Initially, we demonstrate an IL-6 inducing activity of the phagocytic cells stimulant, tuftsin, on murine macrophages. This activity was documented only in the presence of antigen, either KLH or lysozyme. The augmentation was dose dependent, with optimal activity at a concentration of 200 and 20 nM, respectively. The chimeric peptides, either H2N-tuftsin-THF-gamma 2-OH or H2N-THF-gamma 2-tuftsin-OH, were also evaluated in the IL-6 system in the presence of the more potent antigen, KLH. The IL-6 inducing effect was maintained, although maximal activity appeared only at a concentration an order of magnitude greater than that of tuftsin. The chimeric peptides were further tested in an assay evaluating enhancement in murine bone marrow myeloid colony formation, a system in which THF-gamma 2, a T cell stimulant, has an established beneficial effect. The compounds were found to be inactive at the 25-200 ng/ml (14-112 nM) concentration range evaluated. Finally, the chimeric peptides were tested in a combined macrophages-T cells assay, i.e. antigen presentation, in which H2N-tuftsin-THF-gamma 2-OH was found to be more active than either parent peptide, thus representing a possible therapeutic agent.

1-Aminocyclobutanecarboxylic acid derivatives as novel structural elements in bioactive peptides: application to tuftsin analogs

Four novel 2,4-methano amino acids (MAAs, 1-aminocyclobutane-1-carboxylic acids) were synthesized. These include the basic MAA analogs of lysine (16), ornithine (5), and arginine (6) and the neutral methanovaline (22), related to proline. The above MAAs, as well as the MAA analog of homothreonine (7), were incorporated into the peptide chain of the immunomodulatory peptide tuftsin, Thr-Lys-Pro-Arg, known to enhance several biological activities mediated by phagocytic cells. The synthetic methano tuftsin analogs were assayed for their ability to stimulate interleukin-6 (IL-6) secretion by mouse peritoneal macrophages and for their stability in human serum toward enzymatic degradation. It was found that, at 2 x 10(-7) M, [MThr1]tuftsin (24) and an isomer of [MVal3]tuftsin (27a) were considerably more active than the parent peptide in augmentation of cytokine release. [MOrn2]Tuftsin (25) was equally potent. The analogs [MThr1]tuftsin (24) and [MOrn2]tuftsin (25), both pertaining to the proteolytically sensitive Thr-Lys bond of tuftsin, exhibited high resistance to enzymatic hydrolysis as compared to tuftsin. Using specific rabbit anti-tuftsin antibodies in a competitive enzyme-linked immunosorbent assay (ELISA) revealed that none of the MAA analogs can cross-react with tuftsin. It may indicate that the peptides assume global structures different than that of tuftsin.

The plasmacytoma growth inhibitor restrictin-P is an antagonist of interleukin 6 and interleukin 11. Identification as a stroma-derived activin A

A stromal protein, designated restrictin-P, that specifically kills plasma-like cells was purified to homogeneity and shown to be identical with activin A. The specificity to plasma-like cells stemmed from the ability of restrictin-P/activin A to competitively antagonize the proliferation-inducing effects of interleukin (IL) 6 and IL-11. Restrictin-P further interfered with the IL-6-induced secretion of acute phase proteins by HepG2 human hepatoma cells and with the IL-6-mediated differentiation of M1 myeloblasts. A competition binding assay indicated that restrictin-P did not interfere with the binding of IL-6 to its receptor on plasma-like cells, suggesting that it may act by intervening in the signal transduction pathway of the growth factor. Indeed, concomitant addition of restrictin-P and IL-6 to cytokine-deprived B9 hybridoma cells was followed by sustained overexpression of junB gene until cell death occurred, while IL-6 alone caused a transient increase only. This altered response to IL-6 stimulation was accompanied by a moderate increase in STAT protein activation. Thus, in this study, we identified the plasmacytoma growth inhibitor, restrictin-P, as being activin A of stromal origin. It is shown that activin A is an antagonist of IL-6-induced functions and that it modifies the IL-6 signaling pattern.

Combined vaccination with major histocompatibility class I and interleukin 2 gene-transduced melanoma cells synergizes the cure of postsurgical established lung metastases

We have analyzed and compared in detail the malignant phenotypes of, the immune mechanisms induced by, and the immunotherapeutic potentials of B16-F10.9 melanoma cells manipulated by gene transfer to express syngeneic H-2Kb molecules or to secrete the cytokines interleukin 2 (IL-2) or IL-6. Local tumor growth in the footpad of transduced cells is mainly retarded by expression of H-2Kb and IL-2 genes and less by expression of IL-6. Mice given injections intrafootpad of tumorigenic doses of transduced clones manifested significantly reduced postsurgical spontaneous metastasis. After i.v. inoculation, mice given injections of F10.9-Kb expressors did not develop experimental lung metastases; mice given injections of F10.9-IL-6 secretors developed reduced metastatic loads; whereas mice given injections of F10.9-IL-2 secretors developed high loads of lung metastases. On the basis of injections into nude mice, in vivo depletions of CD4+, CD8+, and NK1.1+ cells, and in vitro CTL and natural killer (NK) assays, we show that all F10.9-modified cells induce CD8+ tumor-specific CTL activity and that F10.9-IL-2 secretors also induce nonspecific NK/lymphokine-activated killer cell activity. Vaccinations with F10.9-modified cells were capable of significantly reducing metastatic spread from small established F10.9 footpad tumors. However, in mice carrying preestablished lung metastases, a highly therapeutic effect was achieved only when H-2Kb expressors and IL-2 secretors were combined in vaccination, whereas individual vaccines or other combinations had marginal effects. This higher efficiency of the combined vaccine is due to the combined effect of efficient CTL induction and NK/lymphokine-activated killer cell activity as concluded from depletion of CD8+ and NK1.1 cells during immunotherapy. Thus, the cure of established metastasis can be achieved by the synergistic effects of vaccination with class I and IL-2-transduced tumor cells.

Role of cytokines in termination of the B cell lymphoma dormant state in AKR mice

The high incidence of spontaneous T cell lymphomas in AKR mice (affected by sustained viremia) can be greatly reduced by experimental manipulations including thymus removal at young age or by genetic manipulation changing the Fv-1 allele that controls replication and spread of viruses (establishing the congenic AKR.Fv-1b mice). Although T cell lymphomagenesis is prevented, all these mice were shown to carry endogenous ecotropic provirus-induced potential lymphoma cells (PLCs) in a dormant state. The termination of the dormant state, leading to a high incidence of CD5+ IgM+ B cell lymphomas, was triggered by interference with T cell functions (optimal effect observed following in vivo administration of anti-CD8 moAb), administration of T cell growth factors or by injecting the MCF-247 recombinant virus isolate (from AKR origin) that affects T cell functions. The assumption that the PLC dormant state is maintained through specific immunological mechanisms (involving T cells or antibodies recognizing PLCs) could not be substantiated experimentally. The results of the present studies suggest that T cells provide immunoregulatory signals or factors that contribute to the maintenance of the B cell lymphoma arrest and/or proliferation. Analysis of cytokine levels produced by splenocytes taken from mice during PLC dormancy or its breakdown indicated reduced levels of IL-2 and IL-4 and marked elevation of IL-1 and IL-6 associated with the termination of the dormant state. The effect of IL-1 and IL-6 on terminating the dormant state was demonstrated by injecting these cytokines into PLC carriers, thymectomized 12-month-old AKR mice, yielding 80-85% CD5+ IgM+ B cell lymphomas. The role of IL-6 on B cell lymphoma proliferation was also indicated in MCF-247 mediated termination of dormancy, by inhibiting significantly its effect via in vivo administration of anti IL-6 moAbs.

[Decreased interleukin-1 and interleukin-2 production after splenectomy]

Production of interleukin-1 and of interleukin-2 was measured in 57 splenectomized patients. 11 of them were after elective operations (aged 14-37 years, mean 24) and 46 posttraumatic (aged 20-36, mean 23) and in 20 appropriate controls. There was significant reduction of both interleukins in the splenectomized group, more evident in the elective group. The deficiency was not related to age of patient or time since splenectomy. These results support the view that a consequence of splenectomy is immunoregulatory deficit.

Immune cell defects affect bone remodelling in osteopetrotic op/op mice

The aim of the present work was to further characterize immunological defects in osteopetrosis. The op/op mutant mouse is of particular interest since a marrow cavity develops spontaneously in older animals. The interleukin production (IL-1, IL-2, IL-3, IL-4, IL-6), the presence of macrophage differentiation antigens and the evolution of the bone lesions were studied in osteopetrotic and normal mice. Low levels of IL-1, IL-3 and IL-4 were observed at the age of 6 weeks in the op/op mice. However, at 22 weeks of age, the level of IL-1 and IL-4 returned to normal value in these op/op mice whereas the level of IL-3 remained partially decreased at the same age. Furthermore, macrophage expression of MAC-2 antigen, reduced at 12 weeks of age was found to be normal 10 weeks later. These immunological defects and their recovery seems to be concomitant with the healing of the bone lesions.

Pyknodysostosis: imaging and laboratory observations

Pyknodysostosis is a rare form of sclerosing bone dysplasia with autosomal recessive inheritance. Affected members of two families were assessed as follows: three patients underwent densitometry measurements and bone scans; four patients underwent magnetic resonance imaging (MRI) and an immunological investigation, as well as a detailed endocrinological and biochemical laboratory review. Densitometry measurements revealed values of up to 291% of age-matched normal controls; this increased bone density was mainly in the trabecular bone and not in the cortical bone. The MRI showed the cortex to be of normal thickness, whereas the increase in trabecular bone limited the space within the medullary canal. Bone scans and single photon emission computerized tomography in three patients showed an increased uptake of [99mTc]methylene diphosphonate of up to 538% of age-matched controls, which reflected the increased bone density. Monocyte function tests demonstrated a normal phagocytic capacity, but their killing activity was impaired. Interleukin-1 secretion was also impaired, which may point to the pathogenesis of the disease, in view of its function as an osteoclast activator and its role in bone resorption.

Anti-metastatic vaccination of tumor-bearing mice with IL-2-gene-inserted tumor cells

IL-2 gene was introduced through retroviral vectors into the highly malignant and poorly immunogenic 3LL-D122 clone. Both high and low D122-IL-2 secretors showed elimination of tumorigenicity in syngeneic immune-competent mice; however, in nude mice only the high IL-2 secretor showed reduced tumorigenicity as compared with parental D122 cells. Also, following intravenous inoculation, only the high IL-2 secretor showed reduced generation of metastases, whereas the low IL-2 secretors were as highly metastatic as parental cells. These results seem to indicate that low levels of IL-2 secreted by tumor cells are sufficient to activate T cells, while higher levels are needed in order to activate non-T-cell effectors. D122-IL-2 secretors induced high levels of anti-tumor CTL, while their sensitivity to the lytic activity of these CTL was similar to the sensitivity of D122 cells, thus indicating that the elevation of immunogenicity of IL-2 secretors was essentially due to the secreted IL-2. In accordance with CTL induction, pre-immunization with IL-2 secretors protected mice against subsequent challenge of parental cells. Moreover, immunization in an "immunotherapy protocol" i.e., vaccination of mice carrying an established tumor of parental D122 cells with inactivated D122-IL2 infectants, almost completely eliminated the generation of lung metastases by D122 cells, thus providing a rationale for the use of IL-2 gene transferred tumor cells as a modality for treatment of metastasis.