CD8+ T regulatory cells express the Ly49 Class I MHC receptor and are defective in autoimmune prone B6-Yaa mice.

The immune system includes a subpopulation of CD8(+) T cells equipped to inhibit the expansion of follicular T helper (T(FH)) cells, resulting in suppression of autoantibody production and associated lupus-like disease. These CD8(+) T regulatory (Treg) cells recognize Qa-1/peptide complexes on target T(FH) cells and depend on the IL-15 cytokine for development and function. Here we show that these CD8(+) Treg cells express a triad of surface receptors--CD44, CD122, and the class I MHC receptor Ly49--and account for <5% of CD8(+) T cells. Moreover, the development of systemic lupus erythematosus-like disease in B6-Yaa mutant mice is associated with a pronounced defect in CD8(+) Treg cell activity, suggesting that this regulatory subset may represent an effective therapeutic approach to systemic lupus erythematosus-like autoimmune disease.

Natural immunity to pluripotency antigen OCT4 in humans.

OCT4 is a transcription factor critical for the pluripotency of human embryonal stem (ES) and induced pluipotency stem (IPS) cells. OCT4 is commonly expressed in germ-cell tumors as well as putative cancer stem cells in several tumors, and is a key determinant of oncogenic fate in germ-cell tumors. The capacity of the human immune system to recognize this critical stem-cell gene is not known, but has implications for preventing tumors with ES/IPS-based therapies and targeting stem-cell pathways in cancer. Here we show that OCT4-specific T cells can be readily detected in freshly isolated T cells from most (>80%) healthy donors. The reactivity to OCT4-derived peptides resides primarily in the CD45RO(+) memory T-cell compartment and consists predominantly of CD4(+) T cells. T cells reactive against OCT4-derived peptides can be readily expanded in culture using peptide-loaded dendritic cells. In contrast to healthy donors, immunity to OCT4 was detected in only 35% of patients with newly diagnosed germ-cell tumors. However, chemotherapy of germ-cell tumors led to the induction of anti-OCT4 immunity in vivo in patients lacking such responses at baseline. These data demonstrate the surprising lack of immune tolerance to this critical pluripotency antigen in humans. Harnessing natural immunity to this antigen may allow immune-based targeting of pluripotency-related pathways for prevention of cancers, including those in the setting of ES/IPS-based therapies.

Mitf-Mdel, a novel melanocyte/melanoma-specific isoform of microphthalmia-associated transcription factor-M, as a candidate biomarker for melanoma.

BACKGROUND: Melanoma incidence is on the rise and advanced melanoma carries an extremely poor prognosis. Treatment options, including chemotherapy and immunotherapy, are limited and offer low response rates and transient efficacy. Thus, identification of new melanocyte/melanoma antigens that serve as potential novel candidate biomarkers in melanoma is an important area for investigation. METHODS: Full length MITF-M and its splice variant cDNA were cloned from human melanoma cell line 624 mel by reverse transcription polymerase chain reaction (RT-PCR). Expression was investigated using regular and quantitative RT-PCR in three normal melanocytes (NHEM), 31 melanoma cell lines, 21 frozen melanoma tissue samples, 18 blood samples (peripheral blood mononuclear cell; PBMC) from healthy donors and 12 non-melanoma cancer cell lines, including three breast, five glioma, one sarcoma, two kidney and one ovarian cancer cell lines. RESULTS: A novel splice variant of MITF-M, which we named MITF-Mdel, was identified. The predicted MITF-Mdel protein contains two in frame deletions, 56- and 6- amino acid deletions in exon 2 (from V32 to E87) and exon 6 (from A187 to T192), respectively. MITF-Mdel was widely expressed in melanocytes, melanoma cell lines and tissues, but almost undetectable in non-melanoma cell lines or PBMC from healthy donors. Both isoforms were expressed significantly higher in melanoma tissues than in cell lines. Two of 31 melanoma cell lines expressed only one isoform or the other. CONCLUSION: MITF-Mdel, a novel melanocyte/melanoma-specific isoform of MITF-M, may serve as a potential candidate biomarker for diagnostic and follow-up purposes in melanoma.

Activated CD4+ T cells enhance radiation effect through the cooperation of interferon-gamma and TNF-alpha.

BACKGROUND: Approaches that enhance radiation effect may lead to improved clinical outcome and decrease toxicity. Here we investigated whether activated CD4+ T cells (aCD4) can serve as an effective radiosensitizer. METHODS: CD4+ T cells were activated with anti-CD3 and anti-CD28 mAbs. Hela cells were presensitized with aCD4 or conditioned supernatant (aCD4S) or recombinant cytokines for 2 days, followed gamma-irradiation. The treated cells were cultured for an additional 2 to 5 days for cell proliferation, cell cycle, and western blot assays. For confirmation, other cancer cell lines were also used. RESULTS: Presensitization of tumor cells with aCD4 greatly increased tumor cell growth inhibition. Soluble factors secreted from activated CD4+ T cells were primarily responsible for the observed effect. IFN-gamma seemed to play a major role. TNF-alpha, though inactive by itself, significantly augmented the radiosensitizing activity of IFN-gamma. aCD4S, but not IFN-gamma or IFN-gamma/TNF-alpha combination, was found to enhance the gamma-irradiation-induced G2/M phase arrest. Bax expression was highly upregulated in Hela cells presensitized with aCD4S followed by gamma-irradiation. The radio-sensitizing activity of aCD4 is not uniquely observed with Hela cell line, but also seen with other cancer cell lines of various histology. CONCLUSIONS: Our findings suggest possible molecular and cellular mechanisms that may help explain the radio-sensitization effect of activated lymphocytes, and may provide an improved strategy in the treatment of cancer with radiotherapy.

Activated CD4+ T cells dramatically enhance chemotherapeutic tumor responses in vitro and in vivo.

Chemoimmunotherapy has been widely studied in melanoma, with various degrees of success. One of the most common approaches is the so-called biochemotherapy, which is associated with increased toxicities, but without overall survival benefit. Another conventional strategy is the use of chemotherapy as an immunomodulator to enhance the effect of cancer vaccines or adoptive cell transfer therapy. Based on this approach, recent studies using chemotherapy to prepare the host before the infusion of ex vivo-activated, melanoma Ag-specific tumor-infiltrating lymphocytes and high dose IL-2 resulted in an impressive response rate. However, the development of immunotherapy for the treatment of a broad range of cancer type is still lacking. In this study, we report the development of a simple yet universal approach termed "chemocentric chemoimmunotherapy" that has potential application in the treatment of all cancer types. This technique uses nonspecifically activated CD4(+) T cells as a chemosensitizer before the administration of chemotherapy. Dramatic enhancement of the cytotoxic effect of chemotherapeutic drugs, either active or nonactive as single agents, was observed both in in vitro and in vivo human tumor xenograft models. Soluble factors secreted from activated CD4(+) T cells, likely acting on the tumor and its microenvironment, were responsible for the observed effect. Although IFN-gamma played a major role in the therapeutic outcome, it was consistently found to be inferior to the use of activated CD4(+) T cells in tumor chemosensitization. Our model may provide a plausible mechanism to facilitate further understanding, design and development of improved chemoimmunotherapy in the treatment of cancer.

Dominant role of CD47-thrombospondin-1 interactions in myeloma-induced fusion of human dendritic cells: implications for bone disease.

Lytic bone disease in myeloma is characterized by an increase in multinucleate osteoclasts in close proximity to tumor cells. However, the nature of osteoclast precursors and the mechanisms underlying multinuclearity are less understood. Here we show that culture of myeloma cell lines as well as primary myeloma cells with human dendritic cells (DCs) but not monocytes or macrophages leads to spontaneous cell-cell fusion, which then leads to the facile formation of multinucleate bone-resorbing giant cells. Osteoclastogenesis is cell contact dependent, leading to up-regulation of thrombospondin-1 (TSP-1) in DCs. Disruption of CD47-TSP-1 interaction by TSP-1-blocking antibodies or down-regulation of CD47 on tumor cells by RNA interference abrogates tumor-induced osteoclast formation. Blockade of CD47-TSP-1 interactions also inhibits receptor activator for nuclear factor kappaB ligand- and macrophage colony-stimulating factor-induced formation of osteoclasts from human monocytes. Further, TSP-1 blockade attenuates hypercalcemia induced by parathyroid hormone in vivo. These data point to a role for CD47-TSP-1 interactions in regulating cell-fusion events involved in human osteoclast formation. They also suggest that DCs, known to be enriched in myeloma tumors, may be direct precursors for tumor-associated osteoclasts. Disruption of CD47-TSP-1 interactions or preventing the recruitment of DCs to tumors may provide novel approaches to therapy of myeloma bone disease and osteoporosis.

Immunotherapy of melanoma: a critical review of current concepts and future strategies.

Advanced melanoma is a devastating disease with a very poor overall prognosis. There are only two agents that are approved by the FDA for use in patients with metastatic melanoma: dacarbazine and IL-2. Both agents have an overall response rate well below 20%, with only rare long-term responders noted. Metastatic melanoma is known to be one of the most resistant cancers to a plethora of treatment modalities, such as single-agent and combination chemotherapy, chemoimmunotherapy and immunotherapy with a host of immune stimulators. Indeed, researchers worldwide have recognized the lack of effective therapies and have refocused their efforts on developing novel and cutting-edge strategies of treatment. This is based on an improved understanding of the complex interactions that occur within the tumor microenvironment, and the central role that the host immune system plays in the surveillance of cancer. This review summarizes the recent results of novel immunotherapeutic regimens and focuses on cutting-edge modalities of treatment that encompass new lines of thinking in the war against cancer and, in particular, melanoma.

Serial in vivo loss and in vitro gain of Fas expression and function in human cancerous pancreatic duct cells.

Recent studies have shown the involvement of the Fas system (Fas receptor and its ligand FasL) in cancerous processes. The absence or downregulation of Fas, reported in the majority of human tumors, conflicts with its presence in cancerous cells from the same tumors but maintained in vitro. Recently, the eventual role of environmental factors in the loss of Fas expression, or in the in vivo selection of a Fas-negative cell population has been suggested. We determined the Fas expression and function in the Capan-1 human cancerous pancreatic duct cells over 2 successive passages in vivo separated by a period of 10-20 passages in vitro. We showed that Capan-1 cells express Fas and are sensitive to Fas-mediated apoptosis when maintained in vitro. When these cells were xenografted into nude mice the expression of Fas was lost in the majority of the tumors. Culture of tumor-derived cells exhibited that they became Fas-positive and sensitive to Fas-mediated apoptosis after a short period in vitro. The loss/gain of Fas was reproduced after re-explantation and re-culture of these Fas-expressing cells. Furthermore, RT-PCR evidenced a strong inhibition of Fas, FLICE and FADD mRNAs expression in the xenografts. Our observations indicate that the expression of Fas and its function could depend to factors in the tumoral environment. The in vivo loss of Fas may thus play an important role in the tumor formation and in the evasion of tumor cells from immune surveillance.