Ines Silva

Aldehyde Dehydrogenase in Combination with CD133 Defines Angiogenic Ovarian Cancer Stem Cells That Portend Poor Patient Survival

Markers that reliably identify cancer stem cells (CSC) in ovarian cancer could assist prognosis and improve strategies for therapy. CD133 is a reported marker of ovarian CSC. Aldehyde dehydrogenase (ALDH) activity is a reported CSC marker in several solid tumors, but it has not been studied in ovarian CSC. Here we report that dual positivity of CD133 and ALDH defines a compelling marker set in ovarian CSC. All human ovarian tumors and cell lines displayed ALDH activity. ALDH(+) cells isolated from ovarian cancer cell lines were chemoresistant and preferentially grew tumors, compared with ALDH(-) cells, validating ALDH as a marker of ovarian CSC in cell lines. Notably, as few as 1,000 ALDH(+) cells isolated directly from CD133(-) human ovarian tumors were sufficient to generate tumors in immunocompromised mice, whereas 50,000 ALDH(-) cells were unable to initiate tumors. Using ALDH in combination with CD133 to analyze ovarian cancer cell lines, we observed even greater growth in the ALDH(+)CD133(+) cells compared with ALDH(+)CD133(-) cells, suggesting a further enrichment of ovarian CSC in ALDH(+)CD133(+) cells. Strikingly, as few as 11 ALDH(+)CD133(+) cells isolated directly from human tumors were sufficient to initiate tumors in mice. Like other CSC, ovarian CSC exhibited increased angiogenic capacity compared with bulk tumor cells. Finally, the presence of ALDH(+)CD133(+) cells in debulked primary tumor specimens correlated with reduced disease-free and overall survival in ovarian cancer patients. Taken together, our findings define ALDH and CD133 as a functionally significant set of markers to identify ovarian CSCs.

Cryptic B cell response to renal transplantation

Transplantation reliably evokes allo‐specific B cell and T cell responses in mice. Yet, human recipients of kidney transplants with normal function usually exhibit little or no antibody specific for the transplant donor during the early weeks and months after transplantation. Indeed, the absence of antidonor antibodies is taken to reflect effective immunosuppressive therapy and to predict a favorable outcome. Whether the absence of donor‐specific antibodies reflects absence of a B cell response to the donor, tolerance to the donor or immunity masked by binding of donor‐specific antibodies to the graft is not known. To distinguish between these possibilities, we devised a novel ELISPOT, using cultured donor, recipient and third‐party fibroblasts as targets. We enumerated donor‐specific antibody‐secreting cells in the blood of nine renal allograft recipients with normal kidney function before and after transplantation. Although none of the nine subjects had detectable donor‐specific antibodies before or after transplantation, all exhibited increases in the frequency of donor‐specific antibody‐secreting cells eight weeks after transplantation. The responses were directed against the donor HLA‐class I antigens. The increase in frequency of donor‐specific antibody‐secreting cells after renal transplantation indicates that B cells respond specifically to the transplant donor more often than previously thought.

Identifying alemtuzumab as an anti-myeloid cell antiangiogenic therapy for the treatment of ovarian cancer

BackgroundMurine studies suggest that myeloid cells such as vascular leukocytes (VLC) and Tie2+ monocytes play a critical role in tumor angiogenesis and vasculogenesis. Myeloid cells are a primary cause of resistance to anti-VEGF therapy. The elimination of these cells from the tumor microenvironment significantly restricts tumor growth in both spontaneous and xenograft murine tumor models. Thus animal studies indicate that myeloid cells are potential therapeutic targets for solid tumor therapy. Abundant VLC and Tie2+ monocytes have been reported in human cancer. Unfortunately, the importance of VLC in human cancer growth remains untested as there are no confirmed therapeutics to target human VLC.MethodsWe used FACS to analyze VLC in ovarian and non-ovarian tumors, and characterize the relationship of VLC and Tie2-monocytes. We performed qRT-PCR and FACS on human VLC to assess the expression of the CD52 antigen, the target of the immunotherapeutic Alemtuzumab. We assessed Alemtuzumabs ability to induce complement-mediated VLC killing in vitro and in human tumor ascites. Finally we assessed the impact of anti-CD52 immuno-toxin therapy on murine ovarian tumor growth.ResultsHuman VLC are present in ovarian and non-ovarian tumors. The majority of VLC appear to be Tie2+ monocytes. VLC and Tie2+ monocytes express high levels of CD52, the target of the immunotherapeutic Alemtuzumab. Alemtuzumab potently induces complement-mediated lysis of VLC in vitro and ex-vivo in ovarian tumor ascites. Anti-CD52 immunotherapy targeting VLC restricts tumor angiogenesis and growth in murine ovarian cancer.ConclusionThese studies confirm VLC/myeloid cells as therapeutic targets in ovarian cancer. Our data provide critical pre-clinical evidence supporting the use of Alemtuzumab in clinical trials to test its efficacy as an anti-myeloid cell antiangiogenic therapeutic in ovarian cancer. The identification of an FDA approved anti-VLC agent with a history of clinical use will allow immediate proof-of-principle clinical trials in patients with ovarian cancer.

Human Mesenchymal Stromal Cells Attenuate Graft‐Versus‐Host Disease and Maintain Graft‐Versus‐Leukemia Activity Following Experimental Allogeneic Bone Marrow Transplantation

We sought to define the effects and underlying mechanisms of human, marrow‐derived mesenchymal stromal cells (hMSCs) on graft‐versus‐host disease (GvHD) and graft‐versus‐leukemia (GvL) activity. Irradiated B6D2F1 mice given C57BL/6 BM and splenic T cells and treated with hMSCs had reduced systemic GvHD, donor T‐cell expansion, and serum TNFα and IFNγ levels. Bioluminescence imaging demonstrated that hMSCs redistributed from lungs to abdominal organs within 72 hours, and target tissues harvested from hMSC‐treated allogeneic BMT (alloBMT) mice had less GvHD than untreated controls. Cryoimaging more precisely revealed that hMSCs preferentially distributed to splenic marginal zones and regulated T‐cell expansion in the white pulp. Importantly, hMSCs had no effect on in vitro cytotoxic T‐cell activity and preserved potent GvL effects in vivo. Mixed leukocyte cultures containing hMSCs exhibited decreased T‐cell proliferation, reduced TNFα, IFNγ, and IL‐10 but increased PGE2 levels. Indomethacin and E‐prostanoid 2 (EP2) receptor antagonisms both reversed while EP2 agonism restored hMSC‐mediated in vitro T‐cell suppression, confirming the role for PGE2. Furthermore, cyclo‐oxygenase inhibition following alloBMT abrogated the protective effects of hMSCs. Together, our data show that hMSCs preserve GvL activity and attenuate GvHD and reveal that hMSC biodistribute to secondary lymphoid organs wherein they attenuate alloreactive T‐cell proliferation likely through PGE2 induction. Stem Cells 2015;33:601–614

Endothelin receptor-A is required for the recruitment of antitumor T cells and modulates chemotherapy induction of cancer stem cells

Background: The endothelin receptor-A (ETRA) plays an important role in tumor cell migration, metastasis, and proliferation. The endothelin receptor B (ETRB) plays a critical role in angiogenesis and the inhibition of anti-tumor immune cell recruitment. Thus dual blockade of ETRA and ETRB could have significant anti-tumor effects. Results: Dual ETRA/ETRB blockade with macitentan (or the combination of the ETRA and ETRB antagonists BQ123 and BQ788) did not enhance antitumor immune cell recruitment. In vitro studies demonstrate that ETRA inhibition prevents the induction of ICAM1 necessary for immune cell recruitment. When used as a single agent against human tumor xenografts, macitentan demonstrated non-significant anti-tumor activity. However, when used in combination with chemotherapy, macitentan specifically reduced tumor growth in cell lines with CD133+ cancer stem cells. We found that ETRA is primarily expressed on CD133+ CSC in both cell lines and primary human tumor cells. ETRA inhibition of CSC prevented chemotherapy induced increases in tumor stem cells. Furthermore, ETRA inhibition in combination with chemotherapy reduced the formation of tumor spheres. Methods: We tested the dual ETRA/ETRB antagonist macitentan in conjunction with (1) an anti-tumor vaccine and (2) chemotherapy, in order to assess the impact of dual ETRA/ETRB blockade on anti-tumor immune cell infiltration and ovarian tumor growth. In vitro murine and human cell line, tumor sphere assays and tumor xenograft models were utilized to evaluate the effect of ETRA/ETRB blockade on cell proliferation, immune cell infiltration and cancer stem cell populations. Conclusions: These studies indicate a critical role for ETRA in the regulation of immune cell recruitment and in the CSC resistance to chemotherapy.

A Novel Model for Evaluating Therapies Targeting Human Tumor Vasculature and Human Cancer Stem–like Cells

Human tumor vessels express tumor vascular markers (TVM), proteins that are not expressed in normal blood vessels. Antibodies targeting TVMs could act as potent therapeutics. Unfortunately, preclinical in vivo studies testing anti-human TVM therapies have been difficult to do due to a lack of in vivo models with confirmed expression of human TVMs. We therefore evaluated TVM expression in a human embryonic stem cell-derived teratoma (hESCT) tumor model previously shown to have human vessels. We now report that in the presence of tumor cells, hESCT tumor vessels express human TVMs. The addition of mouse embryonic fibroblasts and human tumor endothelial cells significantly increases the number of human tumor vessels. TVM induction is mostly tumor-type-specific with ovarian cancer cells inducing primarily ovarian TVMs, whereas breast cancer cells induce breast cancer specific TVMs. We show the use of this model to test an anti-human specific TVM immunotherapeutics; anti-human Thy1 TVM immunotherapy results in central tumor necrosis and a three-fold reduction in human tumor vascular density. Finally, we tested the ability of the hESCT model, with human tumor vascular niche, to enhance the engraftment rate of primary human ovarian cancer stem-like cells (CSC). ALDH(+) CSC from patients (n = 6) engrafted in hESCT within 4 to 12 weeks whereas none engrafted in the flank. ALDH(-) ovarian cancer cells showed no engraftment in the hESCT or flank (n = 3). Thus, this model represents a useful tool to test anti-human TVM therapy and evaluate in vivo human CSC tumor biology.

Secondary Lymphoid Organs Contribute to, but Are Not Required for the Induction of Graft-versus-Host Responses following Allogeneic Bone Marrow Transplantation: A shifting Paradigm for T Cell Allo-activation

Graft-versus-host disease (GVHD) remains the major complication of allogeneic bone marrow transplantation (allo-BMT). GVHD fundamentally depends upon the activation of donor T cells by host antigen-presenting cells (APCs), but the precise location of these interactions remains uncertain. We examined the role of secondary lymphoid organs (SLO) in the induction of GVHD by using homozygous aly/aly mice that are deficient in lymph nodes (LNs) and Peyers patches (PPs). Lethally irradiated, splenectomized, aly/aly (LN/PP/Sp-/-) mice and sham-splenectomized, aly/+ (LN/PP/Sp+/+) mice received BMT from either syngeneic (aly/aly) or allogeneic, major histocompatibility complex (MHC) disparate donors. Surprisingly, although LN/PP/Sp-/- allo-BMT recipients experience a survival advantage, they developed significant systemic and target organ GVHD that is comparable to LN/PP/Sp+/+ controls. Early after allo-BMT, the activation and proliferation of donor T cells was significantly greater in the BM cavity of LN/PP/Sp-/- mice compared to LN/PP/Sp+/+ controls. Donor T cells in LN/PP/Sp-/- mice demonstrated cytolytic activity in vitro, but Graft vs Leukemia (GVL) activity could be overcome by increasing the tumor burden. These data suggest that SLO contribute to, but are not required for, allogeneic T cell responses, and suggest that the BM may represent an alternative, albeit less efficient site for T cell activation following allo-BMT.

C3d regulates immune checkpoint blockade and enhances antitumor immunity

Despite expression of immunogenic polypeptides, tumors escape immune surveillance by engaging T cell checkpoint regulators and expanding Tregs, among other mechanisms. What orchestrates these controls is unknown. We report that free C3d, a fragment of the third component of complement, inside tumor cells - or associated with irradiated tumor cells and unattached to antigen - recruits, accelerates, and amplifies antitumor T cell responses, allowing immunity to reverse or even to prevent tumor growth. C3d enhances antitumor immunity independently of B cells, NK cells, or antibodies, but it does so by increasing tumor infiltrating CD8+ lymphocytes, by depleting Tregs, and by suppressing expression of programmed cell death protein 1 (PD-1) by T cells. These properties of C3d appear specific for the tumor and dependent on complement receptor 2, and they incur no obvious systemic toxicity. The heretofore unrecognized properties of free C3d suggest that protein might determine the effectiveness of immune surveillance and that increasing availability of the protein might prove advantageous in the treatment or prevention of cancer and premalignant conditions.

Abstract 10: Characterization of ovarian CSC using ALDH and CD133 identifies a cancer stem cell hierarchy

Proceedings: AACR 101st Annual Meeting 2010‐‐ Apr 17‐21, 2010; Washington, DC Recent studies in ovarian cancer suggest that the protein CD133 may be a marker of cancer stem cells (CSC). CSC studies in several solid tumors have identified Aldehyde dehyrogenase (ALDH) enzymatic activity as a CSC marker, however ALDH has not been studied in ovarian cancer. We sought to determine if ALDH alone or in combination with CD133 could better define CSC in ovarian cancer. We analyzed the expression of these markers in 13 consecutive primary human ovarian tumor specimens and 8 cell lines. 70% of primary ovarian tumors analyzed had CD133+ cells detectable in low number in, and many tumor cell lines lacked CD133 expression. In contrast, 100% of the primary human ovarian tumor specimens and ovarian cancer cell lines demonstrated ALDH activity. ALDH+ cells isolated from 6 ovarian cancer cell lines preferentially grew larger tumors at a faster rate compared to ALDH− cells. In some cases ALDH− cells were incapable of generating tumors, suggesting ALDH is a good marker of ovarian CSC in cell lines. Importantly, as few as 1000 ALDH+ cells directly isolated from human ovarian tumors were capable of generating tumors in immune deficient mice. ALDH− cells did not form tumors in mice. Interestingly, when ALDH was used in combination with CD133 to analyze ovarian cancer cell lines we observed greater growth in the ALDH+CD133+ cells compared to ALDH+CD133− cells suggesting a potential hierarchy of the stem cells. Consistent with this, as few as 11 ALDH+CD133+ cells freshly isolated from human tumors were capable of forming tumors in mice. Consistent with a stem cell hierarchy, tumors formed from ALDH+CD133+ cells demonstrated a poorly differentiated histology, whereas tumors formed from ALDH+ cells alone demonstrated a more differentiated histology. Finally analysis of tumors generated from ALDH+ and ALDH+CD133+ tumors demonstrated a significant increase in microvascular density compared to ALDH− tumors. qRT-PCR analysis demonstrated that ALDH+ cells compared to ALDH− cells preferentially express numerous angiogenic factors. Taken together our studies: (1) indicate ALDH as a marker of ovarian CSC, (2) suggest a hierarchy of ovarian cancer stem cell differentiation state, and (3) demonstrates that ovarian CSC are highly angiogenic to recruit vasculature to create a stem cell niche. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 10.

Accommodation and the Fetus

The mammalian fetus usually expresses major histocompatibility antigens not present in the mother. Such incompatibility of major histocompatibility antigens between “ordinary” grafts and the recipient provokes a powerful immune response and rejection of the grafts. Survival of the fetus despite this barrier has been ascribed to a low level of expression of histocompatibility antigens or to maternal immune tolerance or to the existence of a barrier posed by the placenta. Here, we discuss a fourth potential mechanism. The mechanism involves acquired resistance to immune-mediated injury and was originally described in organ transplants found to resist injury by antibodies and complement. The mechanism is called accommodation.