Androgen Receptor Roles in Benign and Malignant Prostate Disease

Androgen deprivation therapy (ADT), which aims to reduce androgen-androgen receptor (AR) signaling, is the normal method of prostate cancer treatment. Despite its early success in suppressing prostate tumor growth, the therapy eventually fails, leading to recurrent hormone-refractory tumor growth. Recent studies have been carried out with stromal cell-specific or fibroblastspecific AR knockout mice or prostate stromal-specific and epithelial-specific AR knockout transgenic mice prostate cancer models and in vitro and in vivo studies of various human prostate cancer cells with knock-in and knock-out of the AR. These have indicated that the AR in prostatic stroma acts as a proliferation stimulator and survival factor, whereas epithelial AR acts as a survival factor for epithelial luminal cells and stromal smooth muscle cell differentiation, and as a suppressor for epithelial basal intermediate cell proliferation. These two opposite roles of the stromal and epithelial AR pose a major challenge for ADT and should be taken into account when developing new therapies targeting AR in selective cells.     

Purified herpes simplex virus thymidine kinase retroviral particles: III. Characterization of bystander killing mechanisms in transfected tumor cells

An important consequence of the suicide gene therapeutic paradigm is the phenomenon of bystander cell killing, the death of adjacent tumor cells not transduced with the thymidine kinase (TK) gene from herpes simplex virus (HSV) after treatment with the antiviral drug, ganciclovir (GCV). Evidence from quantitative in vitro assays of glioma cell lines suggest that both murine and human gliomas are similar in expressing high sensitivity to the bystander effect. In five of six glial tumors examined, the presence of only 5% of HSV-TK-expressing transduced cells in the culture resulted in >90% tumor cell death/stasis after addition of GCV. Several lines of evidence support gap junction intercellular communication (GJIC) as important in the bystander effect. In vitro metabolic assays, performed with GCV in the medium, indicated that more tumor burden was reduced when culture conditions supported cell-cell contact of parental and HSV-TK-transduced cells. Additionally, a double dye transfer assay showed that cell communication through the gap junction is greatest for glioma, less for melanoma, and much less for colorectal carcinoma cell lines. In vitro metabolic assays with mixtures of TK+/TK- homologous tumor cells confirmed that glioma cell lines were more susceptible to bystander killing than melanomas. Assays with chimeric tumor mixtures of TK+/TK - cells showed that the level of the bystander killing obtained was characteristic of the TK-bystander cells. The in vitro findings were confirmed in vivo with GCV-treated homologous and chimeric tumors composed of TK+/TK- cells. Day 21 mean tumor volumes (MTVs) indicated the growths obtained were characteristic of the bystander activity reflective of the nontransduced cell population. Furthermore, nontransduced, high-GJIC cells in a chimeric tumor mass appeared to effectively bridge between transduced tumor cells and poorly communicating nontransduced cells. Finally, the importance of a gap junction protein, such as connexin-43, in facilitating the bystander effect was demonstrated with the HT29 low-GJIC cell line. When the TK-nontransduced cell population expressed connexin-43, a better bystander kill was achieved compared to the parental counterpart.     

Stromal expression of connective tissue growth factor promotes angiogenesis and prostate cancer tumorigenesis

Our previous studies have defined reactive stroma in human prostate cancer and have developed the differential reactive stroma (DRS) xenograft model to evaluate mechanisms of how reactive stroma promotes carcinoma tumorigenesis. Analysis of several normal human prostate stromal cell lines in the DRS model showed that some rapidly promoted LNCaP prostate carcinoma cell tumorigenesis and others had no effect. These differential effects were due, in part, to elevated angiogenesis and were transforming growth factor (TGF)-beta1 mediated. The present study was conducted to identify and evaluate candidate genes expressed in prostate stromal cells responsible for this differential tumor-promoting activity. Differential cDNA microarray analyses showed that connective tissue growth factor (CTGF) was expressed at low levels in nontumor-promoting prostate stromal cells and was constitutively expressed in tumor-promoting prostate stromal cells. TGF-beta1 stimulated CTGF message expression in nontumor-promoting prostate stromal cells. To evaluate the role of stromal-expressed CTGF in tumor progression, either engineered mouse prostate stromal fibroblasts expressing retroviral-introduced CTGF or 3T3 fibroblasts engineered with mifepristone-regulated CTGF were combined with LNCaP human prostate cancer cells in the DRS xenograft tumor model under different extracellular matrix conditions. Expression of CTGF in tumor-reactive stroma induced significant increases in microvessel density and xenograft tumor growth under several conditions tested. These data suggest that CTGF is a downstream mediator of TGF-beta1 action in cancer-associated reactive stroma and is likely to be one of the key regulators of angiogenesis in the tumor-reactive stromal microenvironment.     

Naftopidil, a selective {alpha}1-adrenoceptor antagonist, suppresses human prostate tumor growth by altering interactions between tumor cells and stroma

In prostate cancer, tumor-stroma interactions play a critical role in the promotion of tumorigenesis, and thus the prevention of those interactions is a promising target to suppress tumor growth. Several studies demonstrated that alpha(1)-adrenoceptor (α(1)-AR) antagonists, therapeutic drugs for benign prostatic hyperplasia, have growth inhibitory effects on human prostate cancer (PCa) cells through induction of apoptosis or G(1) cell-cycle arrest. However, their direct actions on stromal cells surrounding cancer cells have not yet been elucidated. In this study, we investigated the effects of subtype-selective α(1)-AR antagonists (naftopidil, tamsulosin, and silodosin) on prostate tumor growth with a focus on the role of stroma, using commercially available fibroblast cells (PrSC). Tumorigenic studies in vivo showed significant reductions in tumor growth when E9 cells (an androgen low-sensitive LNCaP subline) grafted with PrSC were treated with naftopidil. In in vitro analyses, naftopidil and silodosin showed antiproliferative effects on PCa cells regardless of androgen sensitivity and α(1)-AR subtype expression. In PrSC, a strong growth inhibitory effect was observed with naftopidil but not silodosin. Flow cytometric analysis revealed that naftopidil, but not silodosin, induced G(1) cell-cycle arrest in both PCa cells and PrSC. In naftopidil-treated PrSC, total interleukin-6 protein was significantly reduced with increased suppression of cell proliferation. Silodosin induced weak early apoptosis only in PCa cells. These findings demonstrated that naftopidil strongly suppressed cell proliferation of stromal cells, resulting in decreased tumorigenic soluble factor, suggesting that naftopidil might be effective in preventing stromal support of tumor cells.     

Androgen receptor roles in benign and malignant prostate disease

Androgen deprivation therapy (ADT), which aims to reduce androgen-androgen receptor (AR) signaling, is the normal method of prostate cancer treatment. Despite its early success in suppressing prostate tumor growth, the therapy eventually fails, leading to recurrent hormone-refractory tumor growth. Recent studies have been carried out with stromal cell-specific or fibroblast-specific AR knockout mice or prostate stromal-specific and epithelial-specific AR knockout transgenic mice prostate cancer models and in vitro and in vivo studies of various human prostate cancer cells with knock-in and knock-out of the AR. These have indicated that the AR in prostatic stroma acts as a proliferation stimulator and survival factor, whereas epithelial AR acts as a survival factor for epithelial luminal cells and stromal smooth muscle cell differentiation, and as a suppressor for epithelial basal intermediate cell proliferation. These two opposite roles of the stromal and epithelial AR pose a major challenge for ADT and should be taken into account when developing new therapies targeting AR in selective cells.     

Reactive stroma in human prostate cancer: induction of myofibroblast phenotype and extracellular matrix remodeling.

PURPOSE: Generation of a reactive stroma environment occurs in many human cancers and is likely to promote tumorigenesis. However, reactive stroma in human prostate cancer has not been defined. We examined stromal cell phenotype and expression of extracellular matrix components in an effort to define the reactive stroma environment and to determine its ontogeny during prostate cancer progression. EXPERIMENTAL DESIGN: Normal prostate, prostatic intraepithelial neoplasia (PIN), and prostate cancer were examined by immunohistochemistry. Tissue samples included radical prostatectomy specimens, frozen biopsy specimens, and a prostate cancer tissue microarray. A human prostate stromal cell line was used to determine whether transforming growth factor beta1 (TGF-beta1) regulates reactive stroma. RESULTS: Compared with normal prostate tissue, reactive stroma in Gleason 3 prostate cancer showed increased vimentin staining and decreased calponin staining (P < 0.001). Double-label immunohistochemistry revealed that reactive stromal cells were vimentin and smooth muscle alpha-actin positive, indicating the myofibroblast phenotype. In addition, reactive stroma cells exhibited elevated collagen I synthesis and expression of tenascin and fibroblast activation protein. Increased vimentin expression and collagen I synthesis were first observed in activated periacinar fibroblasts adjacent to PIN. Similar to previous observations in prostate cancer, TGF-beta1-staining intensity was elevated in PIN. In vitro, TGF-beta1 stimulated human prostatic fibroblasts to switch to the myofibroblast phenotype and to express tenascin. CONCLUSIONS: The stromal microenvironment in human prostate cancer is altered compared with normal stroma and exhibits features of a wound repair stroma. Reactive stroma is composed of myofibroblasts and fibroblasts stimulated to express extracellular matrix components. Reactive stroma appears to be initiated during PIN and evolve with cancer progression to effectively displace the normal fibromuscular stroma. These studies and others suggest that TGF-beta1 is a candidate regulator of reactive stroma during prostate cancer progression.     

Cotargeting tumor and tumor endothelium effectively inhibits the growth of human prostate cancer in adenovirus-mediated antiangiogenesis and oncolysis combination therapy

Tumor-endothelial interaction contributes to local prostate tumor growth and distant metastasis. In this communication, we designed a novel approach to target both cancer cells and their "crosstalk" with surrounding microvascular endothelium in an experimental hormone refractory human prostate cancer model. We evaluated the in vitro and in vivo synergistic and/or additive effects of a combination of conditional oncolytic adenovirus plus an adenoviral-mediated antiangiogenic therapy. In the in vitro study, we demonstrated that human umbilical vein endothelial cells (HUVEC) and human C4-2 androgen-independent (AI) prostate cancer cells, when infected with an antiangiogenic adenoviral (Ad)-Flk1-Fc vector secreting a soluble form of Flk1, showed dramatically inhibited proliferation, migration and tubular formation of HUVEC endothelial cells. C4-2 cells showed maximal growth inhibition when coinfected with Ad-Flk1-Fc and Ad-hOC-E1, a conditional replication-competent Ad vector with viral replication driven by a human osteocalcin (hOC) promoter targeting both prostate cancer epithelial and stromal cells. Using a three-dimensional (3D) coculture model, we found that targeting C4-2 cells with Ad-hOC-E1 markedly decreased tubular formation in HUVEC, as visualized by confocal microscopy. In a subcutaneous C4-2 tumor xenograft model, tumor volume was decreased by 40-60% in animals treated with Ad-Flk1-Fc or Ad-hOC-E1 plus vitamin D3 alone and by 90% in a combined treatment group, compared to untreated animals in an 8-week treatment period. Moreover, three of 10 (30%) pre-established tumors completely regressed when animals received combination therapy. Cotargeting tumor and tumor endothelium could be a promising gene therapy strategy for the treatment of both localized and metastatic human prostate cancer.     

Inhibition of transforming growth factor-β signals suppresses tumor formation by regulation of tumor microenvironment networks

The tumor microenvironment (TME) consists of cancer cells surrounded by stromal components including tumor vessels. Transforming growth factor-β (TGF-β) promotes tumor progression by inducing epithelial–mesenchymal transition (EMT) in cancer cells and stimulating tumor angiogenesis in the tumor stroma. We previously developed an Fc chimeric TGF-β receptor containing both TGF-β type I (TβRI) and type II (TβRII) receptors (TβRI-TβRII-Fc), which trapped all TGF-β isoforms and suppressed tumor growth. However, the precise mechanisms underlying this action have not yet been elucidated. In the present study, we showed that the recombinant TβRI-TβRII-Fc protein effectively suppressed in vitro EMT of oral cancer cells and in vivo tumor growth in a human oral cancer cell xenograft mouse model. Tumor cell proliferation and angiogenesis were suppressed in tumors treated with TβRI-TβRII-Fc. Molecular profiling of human cancer cells and mouse stroma revealed that K-Ras signaling and angiogenesis were suppressed. Administration of TβRI-TβRII-Fc protein decreased the expression of heparin-binding epidermal growth factor-like growth factor (HB-EGF), interleukin-1β (IL-1β) and epiregulin (EREG) in the TME of oral cancer tumor xenografts. HB-EGF increased proliferation of human oral cancer cells and mouse endothelial cells by activating ERK1/2 phosphorylation. HB-EGF also promoted oral cancer cell-derived tumor formation by enhancing cancer cell proliferation and tumor angiogenesis. In addition, increased expressions of IL-1β and EREG in oral cancer cells significantly enhanced tumor formation. These results suggest that TGF-β signaling in the TME controls cancer cell proliferation and angiogenesis by activating HB-EGF/IL-1β/EREG pathways and that TβRI-TβRII-Fc protein is a promising tool for targeting the TME networks.     

Altered TGF-β signaling in a subpopulation of human stromal cells promotes prostatic carcinogenesis

Carcinoma-associated fibroblasts (CAF) play a critical role in malignant progression. Loss of TGF-β receptor II (TGFβR2) in the prostate stroma is correlated with prostatic tumorigenesis. To determine the mechanisms by which stromal heterogeneity because of loss of TGFβR2 might contribute to cancer progression, we attenuated transforming growth factor beta (TGF-β) signaling in a subpopulation of immortalized human prostate fibroblasts in a model of tumor progression. In a tissue recombination model, loss of TGFβR2 function in 50% of the stromal cell population resulted in malignant transformation of the nontumorigenic human prostate epithelial cell line BPH1. Mixing fibroblasts expressing the empty vector and dominant negative TGFβR2 increased the expression of markers of myofibroblast differentiation [coexpression of vimentin and alpha smooth muscle actin (αSMA)] through elevation of TGF-β1 and activation of the Akt pathway. In combination, these two populations of stromal cells recapitulated the tumor inductive activity of CAFs. TGFβR2 activity in mixed stromal cell populations cultured in vitro caused secretion of factors that are known to promote tumor progression, including TGF-β1, SDF1/CXCL12, and members of the fibroblast growth factor (FGF) and bone morphogenetic protein (BMP) families. In vivo, tissue recombination of fibroblasts overexpressing TGF-β1 and SDF1/CXCL12 not only induced transformation of BPH1 cells, but also promoted a robust growth of highly invasive cells, similar to effects produced by CAFs. While the precise nature and/or origin of the particular stromal cell populations in vivo remain unknown, these findings strongly link heterogeneity in TGF-β signaling to tumor promotion by tumor stromal cells.     

Acceleration of human prostate cancer growth in vivo by factors produced by prostate and bone fibroblasts.

Prostate cancer, the most prevalent cancer affecting men, frequently metastasizes to the axial skeleton where it produces osteoblastic lesions with growth rates often exceeding that of the primary tumor. To evaluate the role of tumor cell-host stromal interaction and stromal specific growth factors (GFs) in prostate cancer growth and progression, we coinoculated athymic mice with human prostate cancer cells (LNCaP) and various nontumorigenic fibroblasts s.c. LNCaP tumor formation was most consistently induced by human bone (MS) fibroblasts (62%), followed by embryonic rat urogenital sinus mesenchymal (rUGM) cells (31%) and Noble rat prostatic fibroblasts (17%), but not by NIH-3T3, normal rat kidney, or human lung CCD16 fibroblasts. Carcinomas formed preferentially in male hosts, demonstrating in vivo androgen sensitivity. The human prostate component of these tumors was confirmed with immunohistochemical staining for prostate-specific antigen (PSA), Northern analysis for PSA expression, and Southern analysis for human repetitive Alu sequences. Elevations in serum PSA paralleled the histomorphological and biochemical findings. LNCaP and fibroblast cell-conditioned media (CM) was used to determine whether autocrine and paracrine mitogenic pathways exist between LNCaP and fibroblast cells in vitro, and various defined GFs were tested to identify possible active factors. Mitogenic assays revealed a 200-300% bidirectional stimulation between LNCaP and bone or prostate fibroblast-derived CM. Lung, normal rat kidney, and 3T3 fibroblast CM were not mitogenic for LNCaP cells. Among the purified GFs tested basic fibroblast growth factor (bFGF) was the most potent mitogen, stimulating LNCaP growth 180% in a concentration-dependent manner. Transforming growth factor alpha and epidermal growth factor were both minimally mitogenic. Coinoculation of LNCaP cells with a slowly absorbed matrix (Gelfoam) absorbed with bFGF or dialyzed and concentrated rUGM or MS CM was also capable of inducing LNCaP tumor formation in vivo. These observations illustrate that fibroblasts differentially modulate prostate cancer growth through the release of paracrine-mediated GFs, possibly including bFGF, and that tumor-stromal cell interactions play an important role in prostate cancer growth and progression.     

Matrix metalloproteinase activity, bone matrix turnover, and tumor cell proliferation in prostate cancer bone metastasis.

BACKGROUND: The metastasis of prostate cancer to bone is associated with a substantial increase in bone matrix turnover. Matrix metalloproteinases (MMPs) play roles in both normal bone remodeling and invasion and metastasis of prostate cancer. This study was designed to determine the role of MMP activity in prostate cancer that has metastasized to bone. METHODS: Single human fetal bone fragments were implanted subcutaneously in immunodeficient mice. Four weeks later, PC3 human prostate cancer cells were injected directly into some of the implants, and daily treatment was begun with batimastat (a broad-spectrum MMP inhibitor). There were six mice (i.e., six implants) in each of four experimental arms: bone alone with and without batimastat and bone injected with PC3 cells with and without batimastat. Bone implants were harvested after 14 days of treatment and analyzed for MMP expression, bone histomorphometry, osteoclast counts, blood vessel density, and tumor cell proliferation and apoptosis. Complementary data were obtained from bone biopsy samples from patients and a bone organ coculture system. All statistical tests were two-sided. RESULTS: MMPs were detected in tumor and stromal cells of clinical specimens and experimental bone implants. In vivo, MMP inhibition reduced the number of osteoclasts per millimeter in PC3-injected implants-from 8.2 (95% confidence interval [CI] = 7.9 to 8.5) to 3.0 (95% CI = 2.3 to 3.7) (P =.006). In addition, it prevented degradation of marrow trabeculae within the bone implants (cross-sectional area of implant occupied by mineralized trabeculae: untreated implant = 29.1% [95% CI = 27.1% to 31.1%], PC3-injected implant = 14.0% [95% CI = 10.9% to 17.1%] [P =.005 versus untreated], and batimastat-treated PC3-injected implant = 27.2% [95% CI = 22.4% to 32.0%] [P =.03 versus PC3 injected alone]). MMP inhibition reduced proliferating tumor cells from 20.8% (95% CI = 19.9% to 21.7%) to 7.4% (95% CI = 5.2% to 9.6%) (P =.006), without affecting angiogenesis or apoptosis. In vitro, MMP inhibition had no toxic effect on PC3 cells but prevented calcium release from bone fragments cocultured with PC3 cells. CONCLUSIONS: MMP activity appears to play an important role in bone matrix turnover when prostate cancer cells are present in bone. Bone matrix turnover and metastatic tumor growth appear to be involved in a mutually supportive cycle that is disrupted by MMP inhibition.     

Drug-induced senescence bystander proliferation in prostate cancer cells in vitro and in vivo

Senescence is a distinct cellular response induced by DNA-damaging agents and other sublethal stressors and may provide novel benefits in cancer therapy. However, in an ageing model, senescent fibroblasts were found to stimulate the proliferation of cocultured cells. To address whether senescence induction in cancer cells using chemotherapy induces similar effects, we used GFP-labelled prostate cancer cell lines and monitored their proliferation in the presence of proliferating or doxorubicin-induced senescent cancer cells in vitro and in vivo. Here, we show that the presence of senescent cancer cells increased the proliferation of cocultured cells in vitro through paracrine signalling factors, but this proliferative effect was significantly less than that seen with senescent fibroblasts. In vivo, senescent cancer cells failed to increase the establishment, growth or proliferation of LNCaP and DU145 xenografts in nude mice. Senescent cells persisted as long as 5 weeks in tumours. Our results demonstrate that although drug-induced senescent cancer cells stimulate the proliferation of bystander cells in vitro, this does not significantly alter the growth of tumours in vivo. Coupled with clinical observations, these data suggest that the proliferative bystander effects of senescent cancer cells are negligible and support the further development of senescence induction as therapy.     

In vivo bystander effect in the intracranial model with rat glioma cells reflects the clonal difference of HSV-TK positive cells

We have investigated clonal variations on the in vivo bystander effect of herpes simplex virus-thymidine kinase (HSV-TK)/ganciclovir (GCV) system, using an intracranial tumor model with 9L rat gliosarcoma cells. For this purpose, we established three 9L clones transduced with HSV-TK gene (9L-TK), each of which had similar TK activity but showed different tumor growth rate in vivo. The use of GCV in vitro confirmed previous reports that the bystander effect was manifest in a confluent culture condition, but not in a low cell density condition. In contrast, the therapeutic benefit of the in vivo bystander effect varied among each 9L-TK clone, and had a positive correlation with the in vivo growth rate of the clone. Thus, the bystander effect seems to reflect the growth rate of TK-positive cells, and these data raise a crucial point for applying the bystander effect to clinical trials.     

Promotion of angiogenesis by ps20 in the differential reactive stroma prostate cancer xenograft model

Human prostate cancer is associated with a reactive stroma typified by an increase in the proportion of myofibroblast type cells and elevated synthesis of extracellular matrix proteins. Increased vascular density has been identified in the reactive stroma compartment adjacent to both precancerous and cancerous prostate lesions. The differential reactive stroma (DRS) prostate cancer xenograft model has been developed to investigate the role of reactive stroma in prostate cancer progression. Using this model, we have shown that human prostate stromal cells promote angiogenesis and growth of LNCaP human prostate carcinoma cell tumors, and that these increases are transforming growth factor (TGF) beta1 regulated. Our laboratory isolated and identified previously the ps20 protein (WFDC1 gene) as a prostate stromal cell secreted protein. The ps20 protein contains a whey acidic protein-type four-disulfide core domain, which is a functional motif characterized by serine protease inhibition activity in a number of whey acidic protein domain-containing proteins. In the present study, we show ps20 expression by normal human prostate stromal smooth muscle cells and vascular smooth muscle cells indicating a possible role of ps20 in vessel wall biology. Using in vitro assays, we show that ps20 promotes endothelial cell motility but has no effect on endothelial cell proliferation. To address the potential effects of ps20 in a tumor microenvironment, we used the DRS model to evaluate both angiogenesis and tumorigenesis of tumors generated under either ps20 or control conditions. DRS tumors generated with LNCaP and human prostate stromal cells in the presence of ps20 showed a 67% increase in microvessel density compared with control tumors. Elevated DRS tumor growth in the ps20-treated tumors was reflected by a 29% increase in wet weight and a 58% increase in volume compared with controls. Similar tumors composed of GeneSwitch-3T3 cells engineered to express ps20-V5-His under mifepristone regulation showed a 129% increase in microvessel density after induction of ps20-V5-His. GeneSwitch-3T3 cells expressing ps20-V5-His were localized to vessel walls in a mural cell (pericyte) position indicating a possible direct stabilizing interaction with endothelial cells. In addition, we show that ps20 mRNA synthesis is induced by TGF-beta1, a known regulator of endothelial cell-pericyte interactions and of stromal cell-induced angiogenesis in DRS tumors. These findings suggest that ps20 may be a TGF-beta1-induced regulator of angiogenesis that functions by either promoting endothelial cell migration or by contributing to pericyte stabilization of newly formed vascular structures.     

Different efficacy of in vivo herpes simplex virus thymidine kinase gene transduction and ganciclovir treatment on the inhibition of tumor growth of murine and human melanoma cells and rat glioblastoma cells.

Initial studies have demonstrated the therapeutic efficacy for cancer treatment of in vivo transfer of the herpes simplex virus thymidine kinase gene followed by ganciclovir (GCV) treatment. However, recent studies have questioned the validity of this approach. Using retroviral vector-producing cells (VPC) as a source for in vivo gene transfer, we evaluated the efficacy of in vivo transduction of malignant cells using three different tumor cell models: B16 murine and IIB-MEL-LES human melanomas and a C6 rat glioblastoma. In vitro studies showed a bystander effect only in C6 cells. In vivo studies showed an inhibition of tumor growth in the two melanoma models when tumor cells were coinjected with VPC-producing retroviral vectors carrying the herpes simplex virus thymidine kinase gene, followed by GCV treatment; however, 100% of mice developed tumors in both models. Under similar experimental conditions, 70% (7 of 10) of syngeneic rats completely rejected stereotactically transferred C6 tumor cells; most of them (5 of 10) showed a prolonged survival. Treating established C6 tumors with VPC-producing retroviral vectors carrying the herpes simplex virus thymidine kinase gene and GCV led to the cure of 33% (4 of 12) of the animals. Rats that rejected tumor growth developed an antitumor immune memory, leading to a rejection of a stereotactic contralateral challenge with parental cells. The immune infiltrate, which showed the presence of T lymphocytes, macrophages, and polymorphonuclear cells at the site of the first injection and mainly T lymphocytes and macrophages at the site of tumor challenge, strengthened the importance of the immune system in achieving complete tumor rejection.     

Prostate tumor progression is mediated by a paracrine TGF-beta/Wnt3a signaling axis

Transforming growth factor (TGF)-beta is an important paracrine factor in tumorigenesis. Ligand binding of the type I and II TGF-beta receptors initiate downstream signaling. The role of stromal TGF-beta signaling in prostate cancer progression is unknown. In mice, the conditional stromal knockout of the TGF-beta type II receptor expression (Tgfbr2(fspKO)) resulted in the development of prostatic intraepithelial neoplasia and progression to adenocarcinoma within 7 months. Clinically, we observed a loss of TGF-beta receptor type II expression in 69% of human prostate cancer-associated stroma, compared to 15% of stroma associated with benign tissues (n=140, P-value <0.0001). To investigate the mechanism of paracrine TGF-beta signaling in prostate cancer progression, we compared the effect of the prostatic stromal cells from Tgfbr2(fspKO) and floxed TGF-beta type II receptor Tgfbr2(floxE2/floxE2) mice on LNCaP human prostate cancer cells in vitro and tissue recombination xenografts. Induction of LNCaP cell proliferation and tumorigenesis was observed by Tgfbr2(fspKO) prostate stroma as a result of elevated Wnt3a expression. Neutralizing antibodies to Wnt3a reversed LNCaP tumorigenesis. The TGF-beta inhibition of Wnt3a expression was in part through the suppression of Stat3 activity on the Wnt3a promoter. In conclusion, the frequent loss of stromal TGF-beta type II receptor expression in human prostate cancer can relieve the paracrine suppression of Wnt3a expression.     

Downregulation of indoleamine-2,3-dioxygenase in cervical cancer cells suppresses tumor growth by promoting natural killer cell accumulation

This study examined the role of the immunosuppressive enzyme indoleamine-2,3-dioxygenase (IDO) in cervical cancer progression and the possible use of this enzyme for cervical cancer therapy. We analyzed IDO protein expression in 9 cervical cancer cell lines (SKG-I, -II, -IIIa, -IIIb, SiHa, CaSki, BOKU, HCS-2 and ME-180) stimulated with interferon-γ. IDO expression was observed in all cell lines except for SKG-IIIb. We transfected the human cervical cancer cell line CaSki that constitutively expresses IDO with a short hairpin RNA vector targeting IDO, and established an IDO-downregulated cell line to determine whether inhibition of IDO mediates cervical cancer progression. IDO downregul-ation suppressed tumor growth in?vivo, without influencing cancer cell growth in?vitro. Moreover, IDO downregulation enhanced the sensitivity of cervical cancer cells to natural killer (NK) cells in?vitro and promoted NK cell accumul-ation in the tumor stroma in?vivo. These findings indicate that downregulation of IDO controls cervical cancer progression by activating NK cells, suggesting IDO as a potential therapy for cervical cancer.