Geetha Rao

Major histocompatibility complex class I-related chain A/B (MICA/B) expression in tumor tissue and serum of pancreatic cancer: Role of uric acid accumulation in gemcitabine-induced MICA/B expression

BackgroundMajor histocompatibility complex class I-related chain A and B (MICA/B) are two stress-inducible ligands that bind the immunoreceptor NKG2D and play an important role in mediating the cyotoxicity of NK and T cells. In this study, we sought to study MICA/B expression in pancreatic cancer and to determine whether and how genotoxic drugs such as gemcitabine can affect MICA/B expression and natural killer cytotoxity.MethodsSeven pancreatic cancer cell lines were analyzed for MICA/B expression by flow cytometry and for their sensitivity to NK-92 cell killing by a 51Cr release assay. MICA/B expression in tumor tissues and sera of pancreatic cancer was analyzed by immunohistochemical staining (IHC) and ELISA, respectively.ResultsTwo MICA/B-positive cell lines were sensitive to the cytotoxic activity of NK-92 cells. Other two MICA/B-positive cell lines and three MICA/B-negative cell lines were resistant to NK-92 cell killing. MICA/B expression was positive in 17 of 25 (68%) pancreatic ductal adenocarcinomas but not in normal pancreatic ductal epithelial cells. Serum MICA/B levels were significantly elevated in patients with pancreatic adenocarcinomas but did not correlate with the stage of pancreatic cancer and patient survival. Gemcitabine therapy led to increased serum MICA levels in 6 of 10 patients with detectable serum MICA. Allopurinol, an inhibitor of xanthine oxidoreductase that converts xanthine to uric acid, blocked uric acid production, MICA/B expression, and sensitivity to NK-92 cell killing toward a PANC-1 cancer cell line exposed to radiation and two genotoxic drugs, gemcitabine and 5-fluorouracil.ConclusionsThe levels of MICA/B expression in serum and tissue of pancreatic cancer are elevated. DNA damage-induced MICA/B expression is mediated through increased uric acid production.

Elevated serum heparanase‐1 levels in patients with pancreatic carcinoma are associated with poor survival

It has previously been shown that heparanase‐1 (HPR1), an endoglycosidase, is up‐regulated in pancreatic carcinoma. The purpose of this study was to test whether serum HPR1 levels in pancreatic carcinoma patients are elevated, and whether higher serum HPR1 levels are associated with a shortened survival.

Activation of the Sonic Hedgehog pathway in thyroid neoplasms and its potential role in tumor cell proliferation

The sonic hedgehog (SHH) pathway is activated in several types of malignancy and plays an important role in tumor cell proliferation and tumorigenesis. SHH binding to a 12-pass transmembrane receptor, Patched (PTCH), leads to freeing of Smoothened (SMO) and subsequent activation of GLI transcription factors. In the present study, we analyzed the expression of SHH, PTCH, SMO, and GLI1 in 31 follicular thyroid adenomas (FTA), 8 anaplastic thyroid carcinomas (ATC), and 51 papillary thyroid carcinomas (PTC) by immunohistochemical staining. More than 65% of FTA, PTC, and ATC specimens stained positive for SHH, PTCH, SMO, and GLI. However, the expression of the genes encoding these four molecules did not correlate with any clinicopathologic parameters, including the age, gender, the status of BRAF gene mutation, tumor stage, local invasion, and metastasis. Three thyroid tumor cell lines (KAT-18, WRO82, and SW1736) all expressed the genes encoding these four molecules. 5-Bromo-2-deoxyuridine labeling and MTT cell proliferation assays revealed that cyclopamine (CP), an inhibitor of the SHH pathway, was able to inhibit the proliferation of KAT-18 and WRO82 cells more effectively than SW1736 cells. CP led to the arrest of cell cycle or apoptosis. Knockdown of SHH and GLI expression by miRNA constructs that target SHH or GLI mRNA in KAT-18 and SW1736 cells led to the inhibition of cell proliferation. Our results suggest that the SHH pathway is widely activated in thyroid neoplasms and may have potential as an early marker of thyroid cancer or as a potential therapeutic target for thyroid cancer treatment.

In Vivo and in Vitro Degradation of Heparan Sulfate (HS) Proteoglycans by HPR1 in Pancreatic Adenocarcinomas LOSS OF CELL SURFACE HS SUPPRESSES FIBROBLAST GROWTH FACTOR 2-MEDIATED CELL SIGNALING AND PROLIFERATION

Heparan sulfate proteoglycans (HSPGs) function as a co-receptor for heparin-binding growth factors, such as fibroblast growth factors (FGFs) and heparin-bound epidermal growth factor (HB-EGF). The HS side chain of HSPGs can be cleaved by HPR1 (heparanase-1), an endoglycosidase that is overexpressed in many types of malignancies. In the present study, we demonstrated that HPR1 expression in pancreatic adenocarcinomas inversely correlated with the presence of heparan sulfate (HS) in the basement membrane. In vitro cell culture study revealed that cell surface HS levels inversely correlated with HPR1 activity in five pancreatic cancer cell lysates and their conditioned media. Heparin and PI-88, two HPR1 inhibitors, were able to increase cell surface HS levels in PANC-1 cells in a dose-dependent manner. The ability of HPR1 to degrade cell surface HS was confirmed by showing that cell surface HS levels were increased in HT1080 cells stably transfected with the HPR1 antisense gene but was decreased in the cells overexpressing HPR1. Further studies showed that PI-88 and heparin were able to stimulate PANC-1 cell proliferation in the absence or presence of exogenous FGF2, whereas exogenous HPR1 was able to inhibit PANC-1 cell proliferation in a dose-dependent manner. Modulation of PANC-1 cell proliferation by HPR1 or HPR1 inhibitors corresponded with the inhibition or activation of the mitogen-activated protein kinase. Our results suggest that HPR1 expressed in pancreatic adenocarcinomas can suppress the proliferation of pancreatic tumor cells in response to the growth factors that require HSPGs as their co-receptors.

Inhibition of p70 S6 Kinase (S6K1) Activity by A77 1726 and Its Effect on Cell Proliferation and Cell Cycle Progress

Leflunomide is a novel immunomodulatory drug prescribed for treating rheumatoid arthritis. It inhibits the activity of protein tyrosine kinases and dihydroorotate dehydrogenase, a rate-limiting enzyme in the pyrimidine nucleotide synthesis pathway. Here, we report that A77 1726, the active metabolite of leflunomide, inhibited the phosphorylation of ribosomal protein S6 and two other substrates of S6K1, insulin receptor substrate-1 and carbamoyl phosphate synthetase 2, in an A375 melanoma cell line. A77 1726 increased the phosphorylation of AKT, p70 S6 (S6K1), ERK1/2, and MEK through the feedback activation of the IGF-1 receptor–mediated signaling pathway. Invitro kinase assay revealed that leflunomide and A77 1726 inhibited S6K1 activity with IC50 values of approximately 55 and 80 μM, respectively. Exogenous uridine partially blocked A77 1726–induced inhibition of A375 cell proliferation. S6K1 knockdown led to the inhibition of A375 cell proliferation but did not potentiate the antiproliferative effect of A77 1726. A77 1726 stimulated bromodeoxyuridine incorporation in A375 cells but arrested the cell cycle in the S phase, which was reversed by addition of exogenous uridine or by MAP kinase pathway inhibitors but not by rapamycin and LY294002 (a phosphoinositide 3-kinase inhibitor). These observations suggest that A77 1726 accelerates cell cycle entry into the S phase through MAP kinase activation and that pyrimidine nucleotide depletion halts the completion of the cell cycle. Our study identified a novel molecular target of A77 1726 and showed that the inhibition of S6K1 activity was in part responsible for its antiproliferative activity. Our study also provides a novel mechanistic insight into A77 1726–induced cell cycle arrest in the S phase.

Mesenchymal Stem Cells Develop Tumor Tropism but Do Not Accelerate Breast Cancer Tumorigenesis in a Somatic Mouse Breast Cancer Model

The role of mesenchymal stem cells (MSCs) on breast cancer progression, growth and tumorigenesis remains controversial or unknown. In the present study, we investigated the role of MSCs on breast tumor induction and growth in a clinically relevant somatic breast cancer model. We first conducted in vitro studies and found that conditioned media (CM) of RCAS-Neu and RCAS-PyMT breast cancer cell lines and tumor cells themselves dramatically increased the proliferation and motility of MSCs and induced morphological changes of MSCs and differentiation into fibroblast-like cells. In contrast, the CM of MSCs inhibited the proliferation of two breast cancer cell lines by arresting the cell cycle at the G0/G1 phase. In vivo studies revealed that fluorescence dye-labeled MSCs migrated into tumor tissues. Unexpectedly, single or multiple intravenous injections of MSCs did not affect the latency of breast cancer in TVA- transgenic mice induced by intraductal injection of the RCAS vector encoding polyoma middle-T antigen (PyMT) or Neu oncogenes. Moreover, MSCs had no effect on RCAS-Neu tumor growth in a syngeneic ectopic breast cancer model. While our studies consistently demonstrated the ability of breast cancer cells to profoundly induce MSCs migration, differentiation, and proliferation, the anti-proliferative effect of MSCs on breast tumor cells observed in vitro could not be translated into an antitumor activity in vivo, probably reflecting the antagonizing or complex effects of MSCs on tumor environment and tumor cells themselves.

Xanthine oxidoreductase is required for genotoxic stress-induced NKG2D ligand expression and gemcitabine-mediated antitumor activity

MICA/B (the major histocompatibility antigen-related chain A and B) and Rae I are stress-inducible ligands for the immune-receptor NKG2D. Mechanisms by which genotoxic stress and DNA damage induce the expression of NKG2D ligands remain incompletely understood. Here, we report that inhibition of xanthine oxidoreductase (XOR) activity by allopurinol or inhibition of XOR expression by gene knockdown abrogated genotoxic stress-induced expression of MICA/B and Rae I in three tumor cell lines. XOR knockdown also blocked gemcitabine-mediated antitumor activity in an orthotopic syngeneic mouse model of breast cancer. As a rate-limiting enzyme in the purine catabolic pathway, XOR generates two end-products, uric acid and reactive oxygen species (ROS). ROS scavenging had an insignificant effect on genotoxic drug-induced MICA/B expression but modestly inhibited radiation-induced MICA/B expression. Exogenous uric acid (in the form of monosodium urate) induced MICA/B expression by activating the MAP kinase pathway. Allopurinol blocked genotoxic stress-induced MAP kinase activation. Our study provides mechanistic insights into genotoxic stress-induced activation of the MAP kinase pathway and suggests that XOR is required for genotoxic stress-induced NKG2D ligand expression and gemcitabine-mediated antitumor activity.

Abstract P4-05-04: Lack of the Effect of Mesenchymal Stem Cells on Breast Cancer Initiation and Growth in a Somatic Mouse Breast Cancer Model

Background: The impact of mesenchymal stem cells (MSCs) on breast cancer (BC) progression and growth remains controversial. Some studies using xenograft BC models in nude mice suggest that MSCs stimulate BC metastases, whereas other studies in syngeneic rat BC models suggest that MSCs suppress BC development and growth. In addition, whether MSCs have a role in BC initiation has not been tested. The objective of this study was to determine if bone marrow-derived MSCs affect BC initiation and progression in vitro and in clinically relevant somatic and synegeneic BC mouse models. Materials and Methods: MSCs were isolated from bone marrows of FVB wild-type mice, cultured, and characterized for their potential to differentiate into adipocytes and express flow-cytometric cell surface markers. MSC-conditioned medium (CM) was used to culture RCAS-Neu and RCAS-PyMT BC cell lines, derived from TVA-transgenic mice infected with an avian retroviral vector encoding Neu or polyoma middle T antigen (PyMT). Cell proliferation was analyzed with CellTiter 96 proliferation assay and 5-bromo-2-deoxyuridine labeling. The effect of RCAS-Neu and RCAS-PyMT cells and their CM on MSC migration was determined with Boyden chamber migration assay. In a somatic BC model, TVA-transgenic mice expressing the receptor for an avian retrovirus vector, RCAS, were infected with RCAS-PyMT vector by intraductal injection and treated with MSC (2x10 6 cells/mouse) by i.v. injection. Mice were observed for BC development by palpation. In a syngeneic BC model, RCAS-Neu BC cells were co-implanted with MSCs (5x10 5 /gland) at the ratios 1:0, 1:0.2, or 1:1 into the fat pad of FVB female mice. BC growth was monitored for 9 weeks. Results: CM from MSC did not significantly affect the proliferation of RCAS-Neu and RCAS-PyMT cells. However, RCAS-Neu and RCAS-PyMT cells and their CM induced morphologic changes in MSC and dramatically increased their motility. In somatic model, MSCs had no effect on BC initiation or growth with the mean tumor latency 27.5±7.5 days in MSC-treated mice and 29±5.5 days in control mice treated with PBS. In syngeneic BC model, there was no significant difference in the growth of RCAS-Neu alone or RCAS-Neu cells co-implanted with MSCs. Since BC in these models does not metastasize to distant organs, it could not be determined whether MSCs affect BC metastases. Discussion: Our results demonstrated that BC cell lines and their CM are able to induce MSCs migration and possibly differentiation. However, MSCs had no effect on BC initiation in a somatic BC model and on tumor growth in a syngeneic BC model. It is possible that the number of MSCs and schedule of MSC injection were not optimized or strong PyMT oncogene rapidly induced BC and overcame the effect of MSCs on BC formation. Experiments are ongoing to determine if multiple administrations of MSCs affect BC development induced by PyMT and Neu oncogenes. Lack of effect of MSCs in BC initiation and progression, if confirmed, will suggest that MSCs are safe for delivering novel antitumor agents for BC treatment. Citation Information: Cancer Res 2010;70(24 Suppl):Abstract nr P4-05-04.