KLF4/GLKF4 is a transcription factor that can have divergent functions in different malignancies. The role of KLF4 in prostate cancer etiology remains unclear. We have recently reported that small double-stranded RNA can induce gene expression by targeting promoter sequence in a phenomenon referred to as RNA activation (RNAa). In this study, we examine KLF4 levels in prostate cancer tissue and utilize RNAa as a tool for gene overexpression to investigate its function. Expression analysis indicated that KLF4 is significantly downregulated in prostate cancer cell lines compared with nontumorigenic prostate cells. Meta-analysis of existing cDNA microarray data also revealed that KLF4 is frequently depleted in prostate cancer tissue with more pronounced reduction in metastases. In support, tissue microarray analysis of tumors and patient-matched controls indicated downregulation of KLF4 in metastatic tumor samples. Logistic regression analysis found that tumors with a KLF4 staining score less than 5 had a 15-fold higher risk for developing metastatic prostate cancer (P = 0.001; 95% confidence interval, 3.0–79.0). In vitro analysis indicated that RNAa-mediated overexpression of KLF4 inhibited prostate cancer cell proliferation and survival and altered the expression of several downstream cell-cycle–related genes. Ectopic expression of KLF4 via viral transduction recapitulated the RNAa results, validating its inhibitory effects on cancer growth. Reactivation of KLF4 also suppressed migration and invasion of prostate cancer cells. These results suggest that KLF4 functions as an inhibitor of tumor cell growth and migration in prostate cancer and decreased expression has prognostic value for predicting prostate cancer metastasis. Cancer Res; 70(24); 10182–91. ©2010 AACR.
KLF4/GKLF (gut-enriched Krüpple-like factor) is a member of the Krüpple-like factor subfamily of zinc finger proteins. Inactivation or silencing of KLF4 has been observed in a number of human cancers including gastrointestinal, pancreas, bladder, and lung cancer (1–4). Deletion of KLF4 in mouse models leads to abnormal differentiation, increased proliferation, and formation of intestinal adenomas in the colon and gastric epithelia (5–7). Ectopic expression of KLF4 has been shown to inhibit cell proliferation (8, 9), induce apoptosis (9), and promote cell-cycle arrest (3, 9, 10). These observations provide evidence that KLF4 has putative tumor suppressor function in a variety of malignancies and its inactivation may play a pivotal role in cancer progression. However, in the case of squamous cell carcinoma and breast cancer, KLF4 has been reported to promote growth and/or cellular dedifferentiation (11, 12). The ability for KLF4 to behave as a tumor suppressor or oncogene is largely dependent on genetic context of the tissue and/or cancer. For instance, the oncogenic function of KLF4 has been attributed to its ability to directly suppress p53 transcription (11).
Recently, we and others have reported that double-stranded RNA (dsRNA) can activate gene expression by targeting promoter sequence in a process termed RNA activation (RNAa; refs. 13–16). This technique alters chromatin structure leading to robust and prolonged expression of the endogenous target gene (13, 14). As such, RNAa has potential to be a useful tool for interrogating gene function by serving as an alternative to traditional vector-based systems and an attractive strategy to activate tumor suppressor genes for the treatment of cancer.
The role of KLF4 in prostate cancer etiology has never been examined. In this study, we show that KLF4 is downregulated in prostate cancer with metastases and utilize RNAa and vector-mediated overexpression to investigate its function. Our results indicate that KLF4 functions as an inhibitor of tumor progression in prostate cancer and decreased expression has prognostic value for predicting prostate cancer metastasis. We also demonstrate that RNAa can be utilized as a research tool to evaluate gene function in a manner similar to vector-mediated overexpression.
Materials and Methods
One kilobase of the human KLF4 promoter was scanned for dsRNA target sites based on the rational design rules as previously reported (13, 17). All dsRNA sequences are listed in Supplementary Table S1.
Cell culture and transfection
PC-3, DU145, DuPro, LNCaP, RV1, C4-2, and BPH1 cells were maintained in RPMI-1640 medium supplemented with 10% fetal bovine serum (FBS), 2 mmol/L l-glutamine, penicillin (100 U/mL), and streptomycin (100 μg/mL) in a humidified atmosphere of 5% CO2 maintained at 37°C. RWPE-1 and PWR-1E cells were cultured in serum-free keratinocyte medium supplemented with 5 ng/mL human recombinant epidermal growth factor, and 0.05 mg/mL bovine pituitary extract. Transfection of dsRNA was carried out as previously described (13, 17). RV1 and C4-2 cell lines were a gift from Dr. Benyi Li (University of Kansas, Kansas City, KS). BPH1 cells were acquired from the University of California, San Francisco Cell Culture Facility. All other cell lines were obtained from American Type Culture Collection. No further authentication of the cell lines was done by the authors.
mRNA expression analysis
Total RNA was isolated by using the RNeasy Mini Kit (Qiagen) and reverse transcribed. The resulting cDNA samples were amplified by standard reverse transcription PCR (RT-PCR) or real-time PCR using gene-specific primer sets in conjunction with the Power SyBr Green PCR Master Mix (Applied Biosystems). All primer sequences are listed in Supplementary Table S1.
Comparative metaprofiling of cDNA expression data
The Oncomine Premium database (18) was accessed to perform differential expression analysis of KLF4 in existing prostate cancer microarray data sets by setting a threshold value for gene rank at 10% and P = 0.05.
Cell viability assay
Cells were transfected with dsRNA for approximately 12 hours. Following treatments, cells were transferred to 96-well microplates and seeded at a density of approximately 800 cells per well. Cell viability was subsequently determined every 24 hours for 6 days by using the CellTiter 96 AQueous One Solution (Promega) according to the manufacturer's protocol.
Colony formation assay
Exponentially growing cells were plated at approximately 1,000 cells per well in 6-well plates and transfected with dsRNA. Culture medium was changed every 3 days. Colony formation was analyzed 12 days following transfection by staining cells with 0.05% crystal violet solution for 1 hour.
Flow cytometric analysis of propidium iodide (PI) stained cells was performed as previously described (17).
Retrovirus-based overexpression of KLF4
A retroviral human KLF4 cDNA expression vector (pMXs-hKLF4) was obtained from Addgene. An empty vector (pMXs-EV) was generated by removing the KLF4 gene from the retroviral sequence. Retrovirus particles were generated by transfecting 293FT cells (Invitrogen) with retroviral vectors.
Immunohistochemical staining of tissue microarrays
Construction of tissue microarrays (TMA) from formalin-fixed, paraffin-embedded tissue blocks has been described previously (19). Methods for immunohistochemical (IHC) staining of the TMA slides are available in Supplementary Materials and Methods. The stained tissue arrays were evaluated under a light microscope by a board-certified pathologist and scored based on intensity and proportion of IHC staining as previously described (20). Intensity was scored on a scale of 0 (negative), 1 (weak), 2 (moderate), and 3 (strong), whereas proportion was scored on a scale of 0 (0%), 1 (0.1%–1%), 2 (2%–10%), 3 (11%–33%), 4 (34%–66%), and 5 (67%–100%). A cumulative staining score ranging from 0 to 8 was used for statistical analysis and obtained by combining the intensity and proportion scores.
Statistical significance was determined by using the StatView analysis software (SAS Institute Inc.). The χ2 test was utilized to assess the significance between different proportions. Analysis of continuous variables between different groups was assessed by 1-way analysis of variance followed by Fisher's protected least significant difference test. Logistic regression analysis was used to determine correlation of KLF4 staining score, age, Gleason score, or stage to prostate cancer metastasis. All values are expressed as mean ± SEM unless otherwise indicated. Significance was defined as P < 0.05.
Additional methods for immunoblot analysis, IHC, and invasion/migration assay are listed in Supplementary Materials and Methods.
KLF4 is downregulated in prostate cancer cell lines and tissue samples
We evaluated KLF4 expression levels in a panel of 9 prostate cell lines including 6 cancerous (PC-3, DuPro, DU145, LNCaP, RV-1, and C4-2) and 3 nontumorigenic/benign (RWPE-1, PWR-1E, and BPH1) cell lines. Analysis of mRNA expression by RT-PCR revealed that KLF4 transcript levels are lower in all cancerous cell lines than the nontumorigenic/benign controls (Fig. 1A). Real-time PCR confirmed that KLF4 mRNA expression was significantly downregulated by 80% or more in each prostate cancer cell line compared with levels in RWPE-1 and PWR-1E cells (Fig. 1B). Immunoblot analysis indicated that KLF4 protein levels correlated to that of mRNA in nearly all cell lines (Fig. 1C).
We performed meta-analysis of existing cDNA microarray data sets deposited in the Oncomine database (18). We identified 17 total data sets containing gene expression profiles of PIN (prostatic intraepithelial neoplasia) or primary prostate cancer compared with normal prostate tissue. Analysis of KLF4 levels revealed that it was significantly depleted in 3 of the 17 of the data sets, whereas 2 other profiles showed a trend of KLF4 downregulation in diseased tissue (Supplementary Fig. S1A; refs. 21–24). We further identified and retrieved 11 total data sets that compared metastatic prostate cancer to localized prostate cancer. As shown in Fig. 1D, KLF4 expression was significantly downregulated in metastatic samples in 5 of 11 data sets (22, 24–27). Additional analysis of 3 data sets evaluating gene expression at different grades of prostate cancer also revealed a reverse correlation between KLF4 expression and Gleason score (Supplementary Fig. S1B; refs. 21, 28, 29). Interestingly, no data sets recorded KLF4 upregulation in diseased tissue.
We also assessed KLF4 protein levels by IHC staining of TMAs containing patient-matched normal, tumor, and/or lymph node metastases. Tissues from 29 prostate cancer patients had lymph node metastasis (LN+), whereas 30 prostate cancer patients had tumors without metastasis (LN−). Staining of normal tissue revealed no significant difference in KLF4 levels between LN+ and LN− patients; however, KLF4 was found to be significantly more downregulated in localized tumor tissue from LN+ patients than LN− patients (Fig. 1E, G-H; Supplementary Table S2). Within the LN+ group, KLF4 staining intensity proceeded in the following order: normal tissue > tumor > lymph node metastases (Fig. 1F, I–K). However, IHC staining in the LN− group did not reveal a significant difference in KLF4 expression between normal and tumor tissue (Fig. 1F; Supplementary Table S2). Logistic regression analysis within the LN+ group indicated that tumors with a KLF4 staining score less than 5 had a 15-fold higher risk for developing metastatic prostate cancer (P = 0.001; 95% confidence interval, 3.0–79.0; Supplementary Table S3). Among other clinicopathologic parameters (e.g., age, stage, and Gleason score), KLF4 staining was the sole predictor for metastasis (Supplementary Table S3). Although additional studies are required to validate and extend the IHC data in terms of clinical outcome, these results indicate that KLF4 is frequently depleted in prostate cancer with metastases and has putative prognostic value for predicting metastasis. This would suggest that KLF4 may function as an inhibitor of prostate cancer progression.
RNAa-based overexpression of KLF4 in prostate cancer cells
To explore the function of KLF4 in prostate cancer cells, we decided to activate endogenous KLF4 expression by RNAa. We designed 4 candidate dsRNAs (dsKLF4-525, dsKLF4-496, dsKLF4-261, and dsKLF4-168) according to rules derived from previous studies (13, 17) that targeted the KLF4 promoter at sites ranging from −525 to −168 relative to the transcription start site (Fig. 2A). Each dsRNA was transfected into PC-3 cells and KLF4 expression was evaluated by real-time PCR 3 days after treatment. Compared with controls, dsKLF4-496 and dsKLF4-525 induced KLF4 expression by approximately 3.0- and 1.5-fold, respectively, whereas dsKLF4-168 and dsKLF4-261 did not significantly alter KLF4 levels (Fig. 2B). Time-course experiments further indicated that optimal levels of KLF4 induction (∼4.2-fold) were achieved by day 4 in PC-3 cells (Supplementary Fig. S2).
To determine whether KLF4 was susceptible to RNAa in other prostate cancer cells lines, we transfected DuPro, PC-3, DU145, and LNCaP cells with dsKLF-496. Four days after transfection, dsKLF4-496 induced KLF4 mRNA expression by approximately 16-, 4.6-, and 3.3-fold in DuPro, PC-3, and DU145 cells, respectively (Fig. 2C and D). LNCaP cells were insensitive to dsKLF4-496 as it failed to activate KLF4 expression (data not shown). Consistent with mRNA induction, immunoblot analysis revealed that KLF4 protein levels were also elevated by dsKLF4-496 in each of the sensitive cell lines (Fig. 2E).
Overexpression of KLF4 by RNAa modulates the expression of downstream cell-cycle–related genes
KLF4 regulates the expression of several cell-cycle–related genes including p53, CCNB1, and members of the cyclin-dependent kinase inhibitor family p21, p27, and p57 (3, 11, 30, 31). To determine whether the RNAa-based overexpression of KLF4 modulated the expression of downstream cell-cycle genes, we evaluated protein levels of p21, p27, p57, and CCNB1 in DuPro, PC-3, and DU145 cells following dsKLF4-496 transfection. Expression of p53 was not evaluated because cell lines were either null (e.g., PC-3 and DuPro) or mutant (e.g., DU145) for functional p53 (32). As shown in Figure 3A to C, dsKLF4-496 induced KLF4 levels and altered the expression of several downstream targets in DuPro, PC-3, and DU145 cells. Of interest, p21 and p27 expression was upregulated in all 3 cell lines, whereas CCNB1 was only selectively downregulated in DuPro and PC-3 cells (Fig. 3A–C). Levels of p57 protein also increased in PC-3 and DU145 cells, but markedly decreased in DuPro cells (Fig. 3A–C). To determine whether protein levels correlated to p57 transcription, we utilized real-time PCR to quantify p57 mRNA levels. As shown in Supplementary Fig. S3, p57 mRNA expression increased in all 3 cell lines suggesting p57 is differentially regulated by posttranscriptional mechanisms in DuPro cells following KLF4 activation.
KLF4 has also been shown to downregulate genes involved in chromosome segregation and execution of the mitotic checkpoint including CENPE (centromere protein E), MAD2L1 (mitotic arrest deficient 2-like 1), and BUB1B (budding uninhibited by benzimidazoles 1 homolog B; ref. 30). In fact, mouse embryonic fibroblasts null for KLF4 have chromosome aneuploidy and centrosome amplification (33). Therefore, we evaluated the expression of CENPE, BUB1B, and MAD2L1 in DuPro and PC-3 cells following dsKLF4-496 transfection. In DuPro cells, BUB1B and CENPE expression was downregulated by dsKLF4-496, whereas only CENPE significantly declined in PC-3 cells (Fig. 3D and E). Taken together, these results indicate that the RNAa-based overexpression of KLF4 modulates the expression of several downstream genes that may have functional significance in regulating cell-cycle progression in prostate cancer cells.
KLF4 inhibits growth and survival in prostate cancer cells
Prostate cancer cells transfected with dsKLF4-496 displayed altered morphology and decreased cell density characteristic of impeded growth (Supplementary Fig. S4). Quantitative analysis by MTS assay indicated that PC-3 and DuPro cell viability steadily decreased following dsKLF4-496 transfection (Fig. 4A). By day 6, growth was inhibited by approximately 40% and 70% in PC-3 and DuPro cells, respectively. Clonogenicity assays also revealed that KLF4 overexpression reduced the number and size of colonies formed by PC-3 and DuPro cells (Fig. 4B).
To evaluate the effect of KLF4 activation on cell-cycle distribution, DNA content was analyzed by flow cytometry in cells stained with PI following dsKLF4-496 transfection. In PC-3 cells, dsKLF4-496 caused a significant increase in G1/G0 populations with concurrent declines in S and G2/M populations as compared with control treatments (Fig. 5A and C). Arrest in G2/M phase was associated with KLF4 activation in DuPro cells with proportional declines in S and G1/G0 populations (Fig. 5B and D). KLF4 overexpression by dsKLF4-496 also led to an increase in cells with subdiploid (<2C) DNA content, a marker for DNA fragmentation/apoptosis (Fig. 5A–D). Interestingly, we also observed cell populations in dsKLF4-496 transfected cells with DNA content exceeding levels found in mitotic cells (>4C; Fig. 5A–D). Cell populations with increased ploidy may reflect defective cytokinesis resulting from the downregulation of CENPE and/or BUB1B (Fig. 5D and E). In support, multinucleated cells were routinely observed in images taken of cells transfected with dsKLF4-496 (Supplementary Fig. S5). Taken together, these results indicate that KLF4 overexpression by dsKLF4-496 reduced cell growth and manipulated prostate cancer phenotypes in a manner indicative of altered expression of downstream KLF4-regulated genes.
Vector-based overexpression of KLF4 recapitulates RNAa results
To validate the results obtained through RNAa-mediated activation of KLF4, we utilized a retroviral transduction system to overexpress KLF4 cDNA (pMXs-hKLF4) in prostate cancer cell lines. Infection of KLF4 viral particles caused robust induction of KLF4 protein levels and modulation of several downstream target genes (i.e., 21, p27, p57, and CCNB1) in a pattern similar to RNAa-mediated overexpression including (i) increased levels of p21 and p27, (ii) declines in CCNB1 levels, and (iii) differential regulation of p57 protein between DuPro and PC-3 cells (Supplementary Fig. S6A and B). The subtle variation in downstream gene sensitivity to KLF4 may result from the inherent differences between RNAa-mediated and viral-based overexpression techniques. Morphologically, viral transduction of KLF4 caused changes consistent with growth inhibition, and a noticeable presence of multinucleated cells (Supplementary Fig. S7). Functional studies in PC-3 and DuPro cells revealed that KLF4 transduction decreased cell viability and colony forming potential as compared with control treatments (Supplementary Fig. S8). Vector-based overexpression of KLF4 recapitulated the results obtained by RNAa-mediated KLF4 induction. These data validate RNAa as a technique to study KLF4 overexpression and confirm its function as a putative tumor suppressor in prostate cancer cells.
KLF4 overexpression inhibits prostate cancer cell migration and invasion
Downregulation in metastatic prostate tissue suggests that KLF4 may also play a role in cell migration and invasion. To assess changes in cell migration, PC-3 cells were transduced with KLF4 (pMXs-hKLF4) and allowed to migrate through a transwell membrane into complete media. To control cell number and limit the antigrowth effects of KLF4, equal quantities of cells were transferred to the membrane surface and cell migration was accessed within 20 hours (i.e., when differences in cell viability were minimal; Supplementary Fig. S9). Compared with the empty vector control, overexpression of KLF4 inhibited cell migration; approximately 44% reduction in migratory cells was detected in the KLF4-infected (pMXs-hKLF4) cell population (Fig. 6A and B). Additional analysis via scratch assay also revealed slower cell migration following KLF4 overexpression in PC-3 cells (Supplementary Fig. S10). To evaluate cell invasion, PC-3 cells were transduced with KLF4 (pMXs-hKLF4) and plated on the Matrigel surface. As shown in Figure 6C and D, KLF4 overexpression significantly reduced PC-3 cell invasion; approximately 65% reduction of invading cells was detected in the KLF4-infected (pMXs-hKLF4) cell population as compared with the empty vector control.
Migration/invasion-related genes (e.g., E-cadherin, CXCR4, CTNNB1, MMP11, and TIMP2) have been implicated in prostate cancer metastasis and/or regulated by KLF4. Among the 5 genes, TIMP2 (TIMP metallopeptidase inhibitor 2) was the only gene consistently altered by KLF4 overexpression (data not shown). As shown in Figure 6E, both dsKLF4-496 and KLF4 viral particle (pMXs-hKLF4) increased TIMP2 mRNA levels by approximately 2.5- and 1.8-fold, respectively. Knockdown of KLF4 by siRNA (siKLF4) also correlated with a reduction in TIMP2 levels to suggest that KLF4 may directly regulate TIMP2 expression (Fig. 6F). Taken together, our findings indicate that KLF4 inhibits prostate cancer cell migration/invasion and is associated with elevated TIMP2 expression.
The role of KLF4 in prostate cancer has never been investigated. Within this study, we reveal that KLF4 is downregulated in prostate cancer cell lines and prostate cancer tissue with metastases. Interestingly, all 6 prostate cancer cell lines evaluated in this study, with the exception of RV1, are derived from metastatic prostate tissue (32). Analysis of 47 total data sets from the Oncomine database revealed that no data set recorded KLF4 upregulation in diseased tissue. Rather, the only significant changes in KLF4 expression were downregulation with increased frequency in metastatic sample data sets. Analysis of patient-matched tissues also revealed that low KLF4 immunostaining may have prognostic value for prostate cancer metastasis. Collectively, these data suggest that KLF4 functions as an inhibitor of prostate cancer progression. In support, restoration of KLF4 expression significantly reduced prostate cancer cell viability, clonogenicity, growth, migration, and invasion—features indicative of tumor suppressor function. Such phenotypes are also associated with changes in gene expression known to negatively impact cell growth and migration. For instance, KLF4 induced p27 expression in prostate cancer cell lines and low p27 levels are associated with aggressive/recurrent prostate cancer, whereas its overexpression correlates with growth inhibition in cell culture (34).
KLF4 has also been shown to inhibit migration and invasion in several cancer models (3, 35, 36). Interestingly, forced expression of KLF4 in prostate cancer cells elevated expression of TIMP2, a metalloproteinase thought to function as an inhibitor of metastasis. TIMP2 has been reported to be inactivated via DNA hypermethylation in metastatic prostate cancer tissue and inhibit cancer cell migration (37, 38). Thus, TIMP2 may function as a downstream factor of KLF4 to inhibit cell migration/invasion in prostate cancer.
RNAa-mediated overexpression of KLF4 inhibited cell proliferation/survival and arrested cell-cycle progression. In DuPro cells, KLF4 overexpression resulted in G2/M arrest, whereas accumulation in G1/G0 phases of the cell cycle was detected in PC-3 cells. KLF4 has been shown to cause either G1 or G2 arrest in different cell types based on modulation and function of downstream genes (10, 31, 39). Differential regulation of p57 protein levels between PC-3 and DuPro cells may play a role in delineating alternate phases of cell-cycle arrest; elevated levels of p57 are associated with G1 arrest (40). Declines in CCNB1 may contribute to G2 arrest as KLF4 has been previously shown to prevent entry into mitosis through reductions in CCNB1 levels (10). Based on combination and susceptibility of downstream genes to KLF4 reactivation, DuPro and PC-3 cells were inhibited at different phases of the cell cycle. The ability of KLF4 to inhibit cell-cycle progression at multiple checkpoints is indicative of a gene with potent tumor suppressor-like function. Transfection of dsKLF4-496 also led to a small population of cells with subdiploid DNA content in both DuPro and PC-3 cells. Enhanced cell death may also contribute to the tumor suppressor-like activity of KLF4 in prostate cancer cells.
Vector-based overexpression is the traditional approach to evaluate the function of tumor suppressor genes or oncogenes in cancer cells. However, all vector-based systems require ectopic expression from an exogenous construct. Ectopic expression vectors do not typically resemble natural genes (41, 42). They are frequently created from cDNA libraries or amplicons, which do not contain introns or UTR elements. Such regions can have pivotal effects on endogenous gene function in cancer biology (41). As a laboratory tool, RNAa has the unique ability to enhance endogenous transcription of a targeted gene. Such a technique may allow for a more natural approach at analyzing gene function. In support, RNAa appeared to facilitate a greater measurable effect on downstream gene expression than viral transduction (Fig. 4; Supplementary Fig. S6).
In conclusion, both cDNA and protein expression profiling demonstrated that KLF4 is significantly downregulated in prostate cancer tissue with metastases. Furthermore, decreased KLF4 expression has potential to serve as a strong and independent predictor of prostate cancer metastasis. By using RNAa as a laboratory technique, we revealed that KLF4 inhibits prostate cancer cell growth/survival and arrests cell-cycle progression by modulating the expression of key downstream genes. KLF4 also suppressed prostate cell migration/invasion and upregulated TIMP2. This study reveals that KLF4 functions as a putative tumor suppressor in prostate cancer, and demonstrates the applicability of RNAa to study gene function. Much like RNAi, RNAa offers a new therapeutic approach for combating disease at the genetic level. As such, the ability to reactivate KLF4 by RNAa may have therapeutic potential in the treatment of metastatic prostate cancer.
Disclosure of Potential Conflicts of Interests
No potential conflicts of interests were disclosed.
This work was supported by grants from the National Cancer Institute (NCI) at the National Institutes of Health (NIH; 1R21CA131774-01 to L.C. Li, P50CA89520, University of California San Francisco SPORE Special Program of Research Excellence, PI: M. Shuman), NIH (1R01GM090293-0109 to L.C. Li), DOD Prostate Cancer Research Program (W81XWH-08-1-0260 to L.C. Li and PC061456 to J. Huang), California Institute for Regenerative Medicine (RL1-00660-1 to L.C. Li), American Cancer Society (RSG-07-092-01-TBE to J. Huang), a developmental research award from UCLA SPORE in prostate cancer (PI: R. Reiter) and a challenge award from the Prostate Cancer Foundation (PI: O. Witte).
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Note: Supplementary data for this article are available at Cancer Research Online (http://cancerres.aacrjournals.org/).
- Received July 1, 2010.
- Revision received September 30, 2010.
- Accepted October 19, 2010.
- ©2010 American Association for Cancer Research.