Anne-Françoise Tilkin-Mariamé

Induction of T-cell antitumor immunity and protection against tumor growth by secretion of soluble human CD70 molecules.

One of the strategies to promote an antitumor response is the genetic modification of tumor cells to induce expression of costimulatory molecules. We have tested the capacity of a soluble form of CD70 molecule (sCD70). After construction of a vector carrying the sCD70, we obtained stable sCD70-secreting TS/A tumor cells and allogenic MC57 fibroblasts. In all, 45% of wild-type (wt) tumors were rejected in immunocompetent mice when transfected sCD70-secreting cells were injected three times in the periphery of the wt tumors. Furthermore, the sCD70-secreting TS/A cells induced a protective memory against wt TS/A tumor growth: 70% of the wt tumors used for the challenge were rejected by mice, which had rejected tumors 45 days before in the presence of sCD70-secreting TS/A cells. It was also shown that in vitro mock TS/A tumor cell proliferation was inhibited by splenocytes harvested from mice injected with TS/A cells expressing CD70. Growth kinetics of wt TS/A tumors in immunocompetent versus nude mice suggested that T lymphocytes were implicated in the antitumor response, which was confirmed by membrane expression of specific markers. The data suggest that injection of genetically transfected cells secreting sCD70 in the periphery of wt TS/A tumors induces T-cell-mediated inhibition of tumor growth and builds up a protective antitumor memory.

Geranylgeranyl transferase inhibition stimulates anti-melanoma immune response through MHC Class I and costimulatory molecule expression.

Defective antitumor immune responses are frequent consequences of defects in the expression of major histocompatibility complex (MHC) class I and costimulatory molecules. We demonstrated that statins, inhibitors of HMGCoA reductase, enhance mIFN‐γ induced expression of MHC class I antigens on murine B16F10 melanoma. GGTI‐298, a geranylgeranyl transferase I inhibitor, but not FTI‐277, a farnesyl transferase inhibitor, mimics this effect of statins. This effect is related to peptide transporter protein TAP1 up‐regulation. Simultaneously, GGTI‐298 induces the expression of CD80 and CD86 costimulatory molecules. C3 exoenzyme, which selectively inactivates Rho proteins, phenocopies the effects of GGTI‐298, indicating a role for Rho proteins in these events. Furthermore, the treatment of B16F10 cells with GGTI‐298 or C3 exoenzyme associated with mIFN‐γ induces in vivo tumor growth slowing down in immunocompetent but not in nu/nu syngeneic mice. Both in vivo injections and in vitro restimulation of splenocytes with GGTI‐298‐ and mIFN‐γ‐treated B16F10 cells induces an enhancement of specific CD8 T lymphocytes labeled by TRP‐2/H‐2Kb tetramers. Finally, these effects are not limited to mouse models since they were also reproduced in two human melanoma cell lines. These observations indicate that protein geranylgeranylation as well as Rho protein are critical for costimulatory and IFN‐γ‐dependent MHC class I molecule expression in melanoma.

Blocking Tumor Necrosis Factor α Enhances CD8 T-cell–Dependent Immunity in Experimental Melanoma

TNF plays a dual, still enigmatic role in melanoma, either acting as a cytotoxic cytokine or favoring a tumorigenic inflammatory microenvironment. Herein, the tumor growth of melanoma cell lines expressing major histocompatibility complex class I molecules at high levels (MHC-I(high)) was dramatically impaired in TNF-deficient mice, and this was associated with enhanced tumor-infiltrating CD8(+) T lymphocytes. Immunodepletion of CD8 T cells fully restored melanoma growth in TNF(-/-) mice. Systemic administration of Etanercept inhibited MHC-I(high) melanoma growth in immunocompetent but not in immunodeficient (IFNγ(-/-), nude, or CD8(-/-)) mice. MHC-I(high) melanoma growth was also reduced in mice lacking TNF-R1, but not TNF-R2. TNF(-/-) and TNF-R1(-/-) mice as well as Etanercept-treated WT mice displayed enhanced intratumor content of high endothelial venules surrounded by high CD8(+) T-cell density. Adoptive transfer of activated TNF-R1-deficient or -proficient CD8(+) T cells in CD8-deficient mice bearing B16K1 tumors demonstrated that TNF-R1 deficiency facilitates the accumulation of live CD8(+) T cells into the tumors. Moreover, in vitro experiments indicated that TNF triggered activated CD8(+) T cell death in a TNF-R1-dependent manner, likely limiting the accumulation of tumor-infiltrating CD8(+) T cells in TNF/TNF-R1-proficient animals. Collectively, our observations indicate that TNF-R1-dependent TNF signaling impairs tumor-infiltrating CD8(+) T-cell accumulation and may serve as a putative target to favor CD8(+) T-cell-dependent immune response in melanoma.

In vivo induction of antitumor immunity and protection against tumor growth by injection of CD154-expressing tumor cells

As they should enhance tumor-specific antigen presentation by dendritic cells, tumor cell lines genetically modified to express CD154 molecules have been used in an attempt to induce protective antitumor immunity. Two murine models were used: the major histocompatibility complex (MHC) class I negative melanoma B16F10 and the MHC class I positive mammary adenocarcinoma TS/A. CD154 or mock-transfected B16F10 or TS/A cells were injected subcutaneously into H-2–compatible B6D2 mice. CD154 expression by tumor cells induced a complete rejection (in the TS/A model) or a striking reduction (in the B16F10 model) of modified tumors growth, but also a significant protection against the growth of mock tumor cells injected simultaneously, either mixed with the CD154-expressing tumor cells, or in the other flank of mice. Thirty days after CD154-expressing tumor rejection, splenic lymphocytes from surviving tumor-free mice were able to inhibit tumor proliferation in vitro and significant amounts of IFN-γ were detected in the sera of these mice. Growth kinetics of mock and CD154-expressing tumors in immunocompetent versus nude mice suggest that T lymphocytes and natural killer cells responses are implicated in this antitumor immunity. The injection of CD154-expressing tumor cell induced an antitumor protective response, both locally and distant from the injection site. The effect was most pronounced in MHC class I expressing TS/A tumor model.

Coexpression of CD40L and CD70 by semiallogenic tumor cells induces anti-tumor immunity

The immune system is potentially qualified to detect and eliminate tumor cells, but various mechanisms developed by tumor cells allow tumor escape. Strategies selected to promote antitumor responses have included genetic modifications of tumor cells to induce expression of costimulatory molecules. Moreover, alloantigens can also act as strong enhancers of the immune response. In this work, we have associated the expression of two costimulatory members of the TNF superfamily, CD40L and CD70 along with an allogenic MHC Class I (H-2Kd) molecule expression on melanoma cells (B16F10, H-2b) to favor the antitumor immune response. B16F10 tumor growth slows significantly when CD40L and CD70 are coexpressed by tumor cells and the association with the allogenic molecule (H-2Kd) enhances this effect. Growth kinetics of mock and CD40L-CD70-H-2Kd-expressing B16F10 tumors in immunocompetent versus nu/nu and beige mice suggested that CD8+ T lymphocytes and NK cells were involved in this antitumor immunity. A delay in mock tumor growth was observed when CD40L-CD70-H-2Kd-expressing B16F10 cells and mock tumor cells were injected simultaneously and contralaterally. It was also shown that in vivo immunization of immunocompetent mice with CD40L-CD70-H-2Kd B16F10 tumor cells improved the generation of cytotoxic lymphocytes against the wild-type melanoma cells expressing the syngenic MHC Class I molecule H-2Kb (B16K1). These observations lay a path for new immunotherapeutic trials using semiallogenic fibroblasts expressing costimulatory molecules and tumor-associated antigens.

Melanoma Cells Treated with GGTI and IFN-γ Allow Murine Vaccination and Enhance Cytotoxic Response against Human Melanoma Cells

Background Suboptimal activation of T lymphocytes by melanoma cells is often due to the defective expression of class I major histocompatibility antigens (MHC-I) and costimulatory molecules. We have previously shown that geranylgeranyl transferase inhibition (done with GGTI-298) stimulates anti-melanoma immune response through MHC-I and costimulatory molecule expression in the B16F10 murine model [1]. Methodology/Principal Findings In this study, it is shown that vaccination with mIFN-gand GGTI-298 pretreated B16F10 cells induces a protection against untreated tumor growth and pulmonary metastases implantation. Furthermore, using a human melanoma model (LB1319-MEL), we demonstrated that in vitro treatment with hIFN-γ and GGTI-298 led to the up regulation of MHC-I and a costimulatory molecule CD86 and down regulation of an inhibitory molecule PD-1L. Co-culture experiments with peripheral blood mononuclear cells (PBMC) revealed that modifications induced by hIFN-γ and GGTI-298 on the selected melanoma cells, enables the stimulation of lymphocytes from HLA compatible healthy donors. Indeed, as compared with untreated melanoma cells, pretreatment with hIFN-γ and GGTI-298 together rendered the melanoma cells more efficient at inducing the: i) activation of CD8 T lymphocytes (CD8+/CD69+); ii) proliferation of tumor-specific CD8 T cells (MelanA-MART1/TCR+); iii) secretion of hIFN-γ; and iv) anti-melanoma specific cytotoxic cells. Conclusions/Significance These data indicate that pharmacological treatment of melanoma cell lines with IFN-γ and GGTI-298 stimulates their immunogenicity and could be a novel approach to produce tumor cells suitable for vaccination and for stimulation of anti-melanoma effector cells.

Melanoma-expressed CD70 is involved in invasion and metastasis

Background:CD70 is a costimulatory molecule of the tumour necrosis factor family expressed in activated immune cells and some solid tumours. In lymphocytes CD70 triggers T cell-mediated cytotoxicity and mitogen-activated protein kinase phosphorylation.Methods:We evaluated the expression of CD70 in biopsies and melanoma cell lines. Using melanoma cell lines positive or not for CD70, we analysed CD70 function on melanoma progression.Results:We report CD70 expression in human melanoma cell lines and tumour cells from melanoma biopsies. This expression was observed in 95% of primary melanomas but only 37% of metastases. Both monomeric and trimeric forms of CD70 were detected in tumour cell membrane fractions, whereas cytoplasmic fractions contained almost exclusively monomeric CD70. In vitro and in vivo experiments demonstrated that CD70 expression inhibited melanoma cell migration, invasion and pulmonary metastasis implantation independently of the tumour immune microenvironment. Increasing the levels of the trimeric form of CD70 through monoclonal antibody binding led to an increase in CD70+ melanoma cell invasiveness through MAPK pathway activation, RhoE overexpression, ROCK1 and MYPT1 phosphorylation decrease, and stress fibres and focal adhesions disappearance.Conclusions:Our results describe a new non-immunological function of melanoma-expressed CD70, which involves melanoma invasiveness through MAPK pathway, RhoE and cytoskeletal modulation.

In vivo Effects in Melanoma of ROCK Inhibition-Induced FasL Overexpression

Ectopic Fas-ligand (FasL) expression in tumor cells is responsible for both tumor escape through tumor counterattack of Fas-positive infiltrating lymphocytes and tumor rejection though inflammatory and immune responses. We have previously shown that RhoA GTPase and its effector ROCK negatively control FasL membrane expression in murine melanoma B16F10 cells. In this study, we found that B16F10 treatment with the ROCK inhibitor H1152 reduced melanoma development in vivo through FasL membrane overexpression. Although H1152 treatment did not reduce tumor growth in vitro, pretreatment of tumor cells with this inhibitor delayed tumor appearance, and slowed tumor growth in C57BL/6 immunocompetent mice. Thanks to the use of mice-bearing mutated Fas receptors (B6/lpr), we found that reduced tumor growth, observed in immunocompetent mice, was linked to FasL overexpression induced by H1152 treatment. Tumor growth analysis in immunosuppressed NUDE and IFN-γ-KO mice highlighted major roles for T lymphocytes and IFN-γ in the H1152-induced tumor growth reduction. Histological analyses of subcutaneous tumors, obtained from untreated versus H1152-treated B16F10 cells, showed that H1152 pretreatment induced a strong intratumoral infiltration of leukocytes. Cytofluorometric analysis showed that among these leukocytes, the number of activated CD8 lymphocytes was increased. Moreover, their antibody-induced depletion highlighted their main responsibility in tumor growth reduction. Subcutaneous tumor growth was also reduced by repeated intravenous injections of a clinical ROCK inhibitor, Fasudil. Finally, H1152-induced ROCK inhibition also reduced pulmonary metastasis implantation independently of T cell-mediated immune response. Altogether, our data suggest that ROCK inhibitors could become interesting pharmacological molecules for melanoma immunotherapy.

Synthesis and Antiviral Activity Evaluation of Nitroporphyrins and Nitrocorroles as Potential Agents against Human Cytomegalovirus Infection

Different nitroporphyrinoid derivatives were synthesized and studied as potential agents against human Cytomegalovirus. Interestingly, two nitrocorroles display strong activity against human Cytomegalovirus with IC 50 < 0.5 μM. These compounds also possess antiproliferative activities without detected in vivo toxicity. Therefore, nitrocorroles appear for the first time as potential active compounds that can be applied in human health.

Influence of histidine β81 of HLA-DR101 on peptide binding and presentation to T-cell receptor

Abstract HA(306-318) is an immunodominant peptide of the hemagglutinin of influenza virus that binds to most human leukocyte antigen (HLA-DR) alleles, while p18(73-85) is a HIV peptide characterized as a DR101 binding peptide. Our results demonstrate that crystal relaxation leads to the loss of a hydrogen bond between the β81 histidine and the HA(306-318) peptide. This histidine is also involved in the binding of superantigens like SEA via a coordination of a zinc atom. To monitor the interaction of these peptides with this histidine of HLA-DR molecules, chemical modification, peptide binding on HLA-DR101 wild type and mutated molecules, and proliferation experiments were conducted, together with molecular simulation of HLA-DR/peptide molecular complexes. Our data suggest a different binding peptide pattern, depending of whether the peptide is HLA-DR101 allele specific or a shared one. Furthermore, tyrosine substitution at position β81 does not affect either peptide binding or HA(306-318) clone-specific T-cell proliferation. On the contrary, the alanine substitution at position HLA-DR101 β81 abrogated both peptide binding and T-cell proliferation. These results suggest that the histidine 81 on the DRβ chain plays an important role in the HLA-DR peptide binding, more likely by polar interactions of the amino acid side chain ring with the peptide.