Benjamin H. Beck

Protective Immunosurveillance and Therapeutic Antitumor Activity of γδ T Cells Demonstrated in a Mouse Model of Prostate Cancer

In contrast to Ag-specific αβ T cells, γδ T cells can kill malignantly transformed cells in a manner that does not require the recognition of tumor-specific Ags. Although such observations have contributed to the emerging view that γδ T cells provide protective innate immunosurveillance against certain malignancies, particularly those of epithelial origin, they also provide a rationale for developing novel clinical approaches to exploit the innate antitumor properties of γδ T cells for the treatment of cancer. Using TRAMP, a transgenic mouse model of prostate cancer, proof-of-concept studies were performed to first establish that γδ T cells can indeed provide protective immunosurveillance against spontaneously arising mouse prostate cancer. TRAMP mice, which predictably develop prostate adenocarcinoma, were backcrossed with γδ T cell-deficient mice (TCRδ−/− mice) yielding TRAMP × TCRδ−/− mice, a proportion of which developed more extensive disease compared with control TRAMP mice. By extension, these findings were then used as a rationale for developing an adoptive immunotherapy model for treating prostate cancer. Using TRAMP-C2 cells derived from TRAMP mice (C57BL/6 genetic background), disease was first established in otherwise healthy wild-type C57BL/6 mice. In models of localized and disseminated disease, tumor-bearing mice treated i.v. with supraphysiological numbers of syngeneic γδ T cells (C57BL/6-derived) developed measurably less disease compared with untreated mice. Disease-bearing mice treated i.v. with γδ T cells also displayed superior survival compared with untreated mice. These findings provide a biological rationale for clinical trials designed to adoptively transfer ex vivo expanded autologous γδ T cells for the treatment of prostate cancer.

The KISS1 metastasis suppressor: A good night kiss for disseminated cancer cells

Re-expression of KISS1 in tumor cell lines allows all antecedent steps of metastasis, but prevents colonization of secondary sites. Because tumor cells have already disseminated by the time of cancer diagnosis, KISS1 may represent a new opportunity for therapeutic intervention. Moreover, numerous clinical reports demonstrate that a loss or reduction of KISS1 expression in different human cancers inversely correlates with tumor progression, metastasis, and survival. Taken together, these observations compel the hypothesis that KISS1 could be of tremendous utility in controlling metastasis in a therapeutic context. In this review, we highlight some key findings from preclinical and clinical studies and discuss strategies whereby KISS1 may be exploited clinically to treat metastases.

KISS1 over-expression suppresses metastasis of pancreatic adenocarcinoma in a xenograft mouse model

Identifying molecular targets for treatment of pancreatic cancer metastasis is critical due to the high frequency of dissemination prior to diagnosis of this lethal disease. Because the KISS1 metastasis suppressor is expressed at reduced levels in advanced pancreatic cancer, we hypothesized that re-expression of KISS1 would reduce metastases. Highly metastatic S2VP10 cells expressing luciferase (S2VP10L) were transfected with a FLAG-tagged version of KISS1 (KFM), KFMΔSS (with deleted secretion signal sequence), or pcDNA3 control plasmid (CP) and expression was confirmed by RTQ-PCR. SCID mice were implanted orthotopically with S2VP10L cells or transfectants and tumor growth and metastases were monitored using bioluminescence imaging. Mice with S2VP10L-KISS1 tumors developed fewer liver (98%) and lung (99%) metastases than S2VP10L. Unexpectedly, mice with S2VP10L-KFMΔSS tumors also had reduced liver and lung metastases, but had more metastases than mice with S2VP10L-KISS. KISS1 protein was found in the cytoplasm of both KFMΔSS and KISS1-expressing orthotopic tumors by immunohistochemistry. Metastases were not found in lungs of mice with S2VP10L-KISS1 tumors; whereas, KFMΔSS lung sections had regions of concentrated KISS1 staining, suggesting that secretion of KISS1 is needed to reduce metastasis significantly. These data suggest induction of KISS1 expression has potential as an adjuvant treatment for pancreatic cancer.

Adoptively transferred ex vivo expanded γδ-T cells mediate in vivo antitumor activity in preclinical mouse models of breast cancer

In contrast to antigen-specific αβ-T cells (adaptive immune system), γδ-T cells can recognize and lyse malignantly transformed cells almost immediately upon encounter in a manner that does not require the recognition of tumor-specific antigens (innate immune system). Given the well-documented capacity of γδ-T cells to innately kill a variety of malignant cells, efforts are now actively underway to exploit the antitumor properties of γδ-T cells for clinical purposes. Here, we present for the first time preclinical in vivo mouse models of γδ-T cell-based immunotherapy directed against breast cancer. These studies were explicitly designed to approximate clinical situations in which adoptively transferred γδ-T cells would be employed therapeutically against breast cancer. Using radioisotope-labeled γδ-T cells, we first show that adoptively transferred γδ-T cells localize to breast tumors in a mouse model (4T1 mammary adenocarcinoma) of human breast cancer. Moreover, by using an antibody directed against the γδ-T cell receptor (TCR), we determined that localization of adoptively transferred γδ-T cells to tumor is a TCR-dependant process. Additionally, biodistribution studies revealed that adoptively transferred γδ-T cells traffic differently in tumor-bearing mice compared to healthy mice with fewer γδ-T cells localizing into the spleens of tumor-bearing mice. Finally, in both syngeneic (4T1) and xenogeneic (2Lmp) models of breast cancer, we demonstrate that adoptively transferred γδ-T cells are both effective against breast cancer and are otherwise well-tolerated by treated animals. These findings provide a strong preclinical rationale for using ex vivo expanded adoptively transferred γδ-T cells as a form of cell-based immunotherapy for the treatment of breast cancer. Additionally, these studies establish that clinically applicable methods for radiolabeling γδ-T cells allows for the tracking of adoptively transferred γδ-T cells in tumor-bearing hosts.

Homotypic Gap Junctional Communication Associated with Metastasis Suppression Increases with PKA Activity and Is Unaffected by PI3K Inhibition

Loss of gap junctional intercellular communication (GJIC) between cancer cells is a common characteristic of malignant transformation. This communication is mediated by connexin proteins that make up the functional units of gap junctions. Connexins are highly regulated at the protein level and phosphorylation events play a key role in their trafficking and degradation. The metastasis suppressor breast cancer metastasis suppressor 1 (BRMS1) upregulates GJIC and decreases phosphoinositide-3-kinase (PI3K) signaling. On the basis of these observations, we set out to determine whether there was a link between PI3K and GJIC in tumorigenic and metastatic cell lines. Treatment of cells with the well-known PI3K inhibitor LY294002, and its structural analogue LY303511, which does not inhibit PI3K, increased homotypic GJIC; however, we found the effect to be independent of PI3K/AKT inhibition. We show in multiple cancer cell lines of varying metastatic capability that GJIC can be restored without enforced expression of a connexin gene. In addition, while levels of connexin 43 remained unchanged, its relocalization from the cytosol to the plasma membrane was observed. Both LY294002 and LY303511 increased the activity of protein kinase A (PKA). Moreover, PKA blockade by the small molecule inhibitor H89 decreased the LY294002/LY303511-mediated increase in GJIC. Collectively, our findings show a connection between PKA activity and GJIC mediated by PI3K-independent mechanisms of LY294002 and LY303511. Manipulation of these signaling pathways could prove useful for antimetastatic therapy.

Ubiquitous Brms1 expression is critical for mammary carcinoma metastasis suppression via promotion of apoptosis

Morbidity and mortality of breast cancer patients are drastically increased when primary tumor cells are able to spread to distant sites and proliferate to become secondary lesions. Effective treatment of metastatic disease has been limited; therefore, an increased molecular understanding to identify biomarkers and therapeutic targets is needed. Breast cancer metastasis suppressor 1 (BRMS1) suppresses development of pulmonary metastases when expressed in a variety of cancer types, including metastatic mammary carcinoma. Little is known of Brms1 function throughout the initiation and progression of mammary carcinoma. The goal of this study was to investigate mechanisms of Brms1-mediated metastasis suppression in transgenic mice that express Brms1 using polyoma middle T oncogene-induced models. Brms1 expression did not significantly alter growth of the primary tumors. When expressed ubiquitously using a β-actin promoter, Brms1 suppressed pulmonary metastasis and promoted apoptosis of tumor cells located in the lungs but not in the mammary glands. Surprisingly, selective expression of Brms1 in the mammary gland using the MMTV promoter did not significantly block metastasis nor did it promote apoptosis in the mammary glands or lung, despite MMTV-induced expression within the lungs. These results strongly suggest that cell type-specific over-expression of Brms1 is important for Brms1-mediated metastasis suppression.

Subsets of ATP-sensitive potassium channel (KATP) inhibitors increase gap junctional intercellular communication in metastatic cancer cell lines independent of SUR expression

Gap junctional intercellular communication (GJIC) regulates cellular homeostasis by propagating signaling molecules, exchanging cellular metabolites, and coupling electrical signals. In cancer, cells exhibit altered rates of GJIC which may play a role in neoplastic progression. KATP channels help maintain membrane polarity and linkages between KATP channel activity and rates of GJIC have been established. The mechanistic relationship has not been fully elucidated. We report the effects of treatment with multiple KATP antagonist compounds on GJIC in metastatic cell lines demonstrating an increase in communication rates following treatment with compounds possessing specificities towards the SUR2 subunit of KATP. These effects remained consistent using cell lines with different expression levels of SUR1 and SUR2, suggesting possible off target effects on GJIC by these compounds.

Pre-osteoblastic MC3T3-E1 cells promote breast cancer growth in bone in a murine xenograft model

The bones are the most common sites of breast cancer metastasis. Upon arrival within the bone microenvironment, breast cancer cells coordinate the activities of stromal cells, resulting in an increase in osteoclast activity and bone matrix degradation. In late stages of bone metastasis, breast cancer cells induce apoptosis in osteoblasts, which further exacerbates bone loss. However, in early stages, breast cancer cells induce osteoblasts to secrete inflammatory cytokines purported to drive tumor progression. To more thoroughly evaluate the role of osteoblasts in early stages of breast cancer metastasis to the bones, we used green fluorescent protein-labeled human breast cancer cell lines MDA-MB-231 and MDA-MB-435, which both induce osteolysis after intra-femoral injection in athymic mice, and the murine pre-osteoblastic cell line MC3T3-E1 to modulate osteoblast populations at the sites of breast cancer metastasis. Breast cancer cells were injected directly into the femur with or without equal numbers of MC3T3-E1 cells. Tumors grew significantly larger when co-injected with breast cancer cells and MC3T3-E1 cells than injected with breast cancer cells alone. Osteolysis was induced in both groups, indicating that MC3T3-E1 cells did not block the ability of breast cancer cells to cause bone destruction. MC3T3-E1 cells promoted tumor growth out of the bone into the extraosseous stroma. These data suggest that breast cancer cells and osteoblasts communicate during early stages of bone metastasis and promote tumor growth.

Dynamics of Circulating γδ T Cell Activity in an Immunocompetent Mouse Model of High-Grade Glioma.

Human γδ T cells are potent effectors against glioma cell lines in vitro and in human/mouse xenograft models of glioblastoma, however, this effect has not been investigated in an immunocompetent mouse model. In this report, we established GL261 intracranial gliomas in syngeneic WT C57BL/6 mice and measured circulating γδ T cell count, phenotype, Vγ/Vδ repertoire, tumor histopathology, NKG2D ligands expression, and T cell invasion at day 10–12 post-injection and at end stage. Circulating γδ T cells transiently increased and upregulated Annexin V expression at post-tumor day 10–12 followed by a dramatic decline in γδ T cell count at end stage. T cell receptor repertoire showed no changes in Vγ1, Vγ4, Vγ7 or Vδ1 subsets from controls at post-tumor day 10–12 or at end stage except for an end-stage increase in the Vδ4 population. Approximately 12% of γδ T cells produced IFN-γ. IL-17 and IL-4 producing γδ T cells were not detected. Tumor progression was the same in TCRδ-/- C57BL/6 mice as that observed in WT mice, suggesting that γδ T cells exerted neither a regulatory nor a sustainable cytotoxic effect on the tumor. WT mice that received an intracranial injection of γδ T cells 15m following tumor placement showed evidence of local tumor growth inhibition but this was insufficient to confer a survival advantage over untreated controls. Taken together, our findings suggest that an early nonspecific proliferation of γδ T cells followed by their depletion occurs in mice implanted with syngeneic GL261 gliomas. The mechanism by which γδ T cell expansion occurs remains a subject for further investigation of the mechanisms responsible for this immune response in the setting of high-grade glioma.

Abstract 3866: The KISS1 metastasis suppressor appears to reverse the Warburg effect by enhancing mitochondria biogenesis.

Cancer cells tend to utilize aerobic glycolysis even under normoxic conditions, which is commonly called the “Warburg Effect.” Aerobic glycolysis often directly correlates with malignant potential. Though its purpose remains unclear, the “Warburg Effect” is thought to confer advantages to proliferation, survival and dissemination to cancer cells by increasing uptake of nutrients into biomass. KISS1 protein is secreted and proteolytically cleaved into kisspeptins (KP) that block the colonization of disseminated metastatic C8161.9 human melanoma cells at secondary sites. In this study, we hypothesized that KISS1 metastasis suppression occurs via regulation of aerobic glycolysis. Comparison of bioenergetic and metabolic aspects of glucose metabolism showed that all KISS1-secreting clones were less invasive, took up less glucose, produced less lactate which corresponds to higher pH[Ex], effects which were reversed when cells were transduced with shRNA to KISS1. The metabolism, invasion, and metastasis changes did not occur when KISS1 was missing the signal peptide (ΔSS). Utilizing a Seahorse bioanalyzer, KISS1, but not ΔSS cells showed significantly decreased extracellular acidification rates, increased O2 consumption and elevated mitochondria reserve capacity, an indicator of mitochondrial condition and a parameter thought to improve the cells’ ability to cope with oxidative stress. KISS1-expressing cells have 30-50% more mitochondria compared to vector or ΔSS-expressing cells. Increased mitochondrial mass was accompanied by significantly increased expression of mitochondrial genes involved in apoptosis and mitophagy, protein processing and trafficking. Increased mitochondrial mass correlated with higher PGC1α considered to be a master co-activator that regulates mitochondrial mass and metabolism. Interestingly, KISS1 differentially affects PGC1α-mediated downstream pathways, i.e. fatty acid synthesis and β-oxidation. KISS1-mediated up-regulation of mitochondria biogenesis appears to rely on KISS1 interaction with NRF1, a major transcription factor of mitochondria biogenesis. KP10 (which can activate the KISS1 receptor) does not alter pH[Ex] since the metastatic tumor cells do not express KISS1R. This paradox - metastasis and metabolic changes require secretion, but responding cells do not have the receptor - raises questions regarding the mechanism. Nonetheless, these data appear to directly connect changes in mitochondria mass, cellular glucose metabolism and metastasis. [Support: CA134581, Natl. Fndn. Cancer Res., Komen SAC110037]. Citation Format: Wen Liu, Benjamin H. Beck, Kedar S. Vaidya, Kevin T. Nash, Anne R. Diers, Kyle P. Feeley, Aimee Landar, Scott W. Ballinger, Danny R. Welch. The KISS1 metastasis suppressor appears to reverse the Warburg effect by enhancing mitochondria biogenesis. [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 3866. doi:10.1158/1538-7445.AM2013-3866