Activation of hepatocyte growth factor/MET signaling initiates oncogenic transformation and enhances tumor aggressiveness in the murine prostate

Emerging evidence has shown that the hepatocyte growth factor (HGF) and its receptor, MET proto-oncogene, receptor tyrosine kinase (MET), promote cell proliferation, motility, morphogenesis, and angiogenesis. Whereas up-regulation of MET expression has been observed in aggressive and metastatic prostate cancer, a clear understanding of MET function in prostate tumorigenesis remains elusive. Here, we developed a conditional Met transgenic mouse strain, H11Met/+:PB-Cre4, to mimic human prostate cancer cells with increased MET expression in the prostatic luminal epithelium. We found that these mice develop prostatic intraepithelial neoplasia after HGF administration. To further assess the biological role of MET in prostate cancer progression, we bred H11Met/+/PtenLoxP/LoxP:PBCre4 compound mice, in which transgenic Met expression and deletion of the tumor suppressor gene Pten occurred simultaneously only in prostatic epithelial cells. These compound mice exhibited accelerated prostate tumor formation and invasion as well as increased metastasis compared with PtenLoxP/LoxP:PB-Cre4 mice. Moreover, prostatic sarcomatoid carcinomas and lesions resembling the epithelial-to-mesenchymal transition developed in tumor lesions of the compound mice. RNA-Seq and qRT-PCR analyses revealed a robust enrichment of known tumor progression and metastasis-promoting genes in samples isolated from H11Met/+/PtenLoxP/LoxP:PB-Cre4 compound mice compared with those from PtenLoxP/LoxP:PB-Cre4 littermate controls. HGF-induced cell proliferation and migration also increased in mouse embryonic fibroblasts (MEFs) from animals with both Met transgene expression and Pten deletion compared with Pten-null MEFs. The results from these newly developed mouse models indicate a role for MET in hastening tumorigenesis and metastasis when combined with the loss of tumor suppressors.

Prostate cancer is the most common malignancy and the second leading cause of cancer mortality in men in the United States (1). The androgen-signaling pathway plays an essential role in prostate tumorigenesis. Thus, androgen deprivation therapy results in a rapid tumor regression and has been routinely used in clinics for the treatment of advanced prostate cancer. However, androgen deprivation therapy eventually fails in nearly all cases of prostate cancer when patients develop castration-resistant prostate cancer (CRPC), 3 which currently lacks curable treatment and claims more than 250,000 lives worldwide each year (2).
Hepatocyte growth factor (HGF) plays a critical role in the regulation of cell growth, cell motility, morphogenesis, and angiogenesis (3). It has been shown that HGF derived from prostate stroma significantly increases proliferation, motility, and invasion of malignant cells through its receptor, c-Met (4,5). The c-Met receptor tyrosine kinase is encoded by MET, a proto-oncogene, and has been shown to play a promotional role in the proliferation and progression of a wide variety of human malignancies, including prostate cancer (4,6). The aberrant expression of HGF and c-Met often correlates with poor prognosis in cancer patients (7). Specifically, up-regulation of c-Met expression was observed in a majority of the metastatic prostate cancer lesions (6, 8 -11). Interestingly, an inverse correlation between the expression of AR and c-Met has been observed in prostate epithelium and prostate cancer cell lines (4,6,8,12,13). An increase of c-Met expression was also observed in castrated rat (4,15) and mouse models (14). Moreover, it has been shown that the AR represses Met expression in prostate cancer cells (16). Accordingly, MET expression appears very limited in normal prostate luminal cells and primary prostate cancer cells (13). The above data imply a critical role of HGF/MET signaling pathways in prostate tumorigenesis.
Whereas overexpression of c-Met is frequently observed in metastatic prostate cancers and positively correlates with prostate cancer progression (17,18), the biological consequence of aberrant Met up-regulation in disease progression and CRPC development is largely unknown. In addition, there is a lack of appropriate mouse models to directly assess an increased expression of c-Met in prostate cancer initiation and progression. In this study, we developed a conditional Met transgenic mouse strain in which the mouse Met transgene was specifically targeted into the H11b locus (19). By intercrossing the Metfloxed mice with PB-Cre4 mice (20), we generated a conditional Met transgenic mouse line, H11 Met/ϩ :PB-Cre4. Conditional expression of the Met transgene in prostatic luminal epithelial cells is achieved by Cre expression, mimicking the condition of human prostate cancer cells with increased MET expression. Intriguingly, H11 Met/ϩ :PB-Cre4 mice develop prostatic intraepithelial neoplasia (PIN) after HGF administration. To assess the effect of Met in prostate cancer progression, we generated H11 Met/ϩ/ Pten LoxP/LoxP :PB-Cre4 compound mice, in which transgenic Met expression and deletion of the tumor suppressor Pten simultaneously co-occur in prostatic epithelial cells. We observed accelerated prostate cancer progression, aggressive tumor invasion, and increased metastasis in these compound mice. Moreover, development of prostatic sarcomatoid carcinomas and lesions resembling epithelial-to-mesenchymal transition is also observed in the prostate of the compound mice. RNA-Seq and qRT-PCR analyses showed a robust enrichment of known tumor progression and metastasis-promoting genes, including Met, Spp1, Fn1, and Cdh2, in samples isolated from H11 Met/ϩ /Pten LoxP/LoxP :PB-Cre4 compound mice compared with those from Pten LoxP/LoxP :PB-Cre4 littermate controls. Our study demonstrates a promotional role of Met in PTEN-mediated oncogenic transformation in prostate tumorigenesis and provides a series of novel and biologically relevant mouse models for investigating prostate cancer initiation and progression.

Activation of HGF/Met signaling in prostatic epithelial cells induces oncogenic transformation in the mouse prostate
Increased c-Met expression has been observed frequently in advanced prostate cancers (4,8). Unfortunately, there is no appropriate mouse model that can be used to directly assess the effect of increased expression of c-Met in prostate cancer initiation and progression. In this study, we generated a conditional Met transgenic line using integrase-mediated transgenic technology (19). A loxP-flanked transcriptional silencing element, LoxP-stop-loxP (LSL) cassette, was inserted between the CAG promoter (21,22) and the FLAG-tagged mouse Met coding sequence (Fig. 1A). Because the CAG promoter is ubiquitously active in most mouse tissues (23), the Met transgene expression in this model can be achieved in a constitutive but tissue-specific manner through Cre recombinase-mediated removal of the LSL cassette (Fig. 1A). To generate prostate-specific expres-sion of the Met transgene, H11 Met/ϩ mice were bred with PB-Cre4 mice, in which Cre expression is regulated by a modified probasin promoter, ARR2PB, in prostatic luminal epithelium (20). To confirm PB-Cre4-mediated genomic recombination, genomic DNA samples were isolated from a variety of tissues of the H11 Met/ϩ :PB-Cre4 mice. Genetic recombination and removal of the LSL cassette from the Met transgene were detected specifically in the prostate, but not in the bladder, testes, kidney, liver, lungs, or tail (Fig. 1B). To detect the Met transgene expression, cell lysates from mouse prostate tissues of H11 Met/ϩ :PB-Cre4 or H11 Met/ϩ only mice were immunoprecipitated with either a FLAG antibody or normal IgG as the control. Transgenic Met expression was detected in the sample immunoprecipitated with the FLAG antibody, but not with an IgG or in the tissue samples isolated from control mice (Fig.  1C). These data demonstrate the specific expression of the Met transgene in the prostate of H11 Met/ϩ :PB-Cre4 mice.
H11 Met/ϩ :PB-Cre4 mice were born at the expected Mendelian ratios and appeared normal with no obvious differences from their WT littermates at birth. Per the recommendations of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee (24), we assessed H11 Met/ϩ :PB-Cre4 mice from birth to 20 months of age and did not observe any obvious pathological changes in the mouse prostate tissues. To assess HGF-Met-mediated effects, we then administered recombinant HGF to 6-month-old H11 Met/ϩ :PB-Cre4 mice as well as age-and sex-matched WT controls and examined their prostates between 8 and 10 months of age (n ϭ 4, each group). We observed pathological lesions of typical low-grade prostatic intraepithelial neoplasia in H11 Met/ϩ :PB-Cre4 mice but not controls (Fig. 1D). Immunohistochemical (IHC) analyses showed strong cytoplasmic immunoreactivity to a Met antibody in atypical cells within PIN lesions (Fig. 1E). Intriguingly, these cells are also reactive to phospho-Met antibody, providing a direct link between the activation of the Met transgene and PIN transformation in the mouse prostate (Fig. 1F). These data demonstrate that activating HGF-Met signaling induces oncogenic transformation in the mouse prostate. However, the transgenic mice did not reveal prostate carcinomas, suggesting that other additional factors may be required in initiating prostate tumor development.

Simultaneous expression of Met and deletion of Pten in the prostate induces earlier onset and more aggressive prostatic carcinomas
Both increased MET expression and aberrant phosphatidylinositol 3-kinase signaling alterations have been observed in advanced and metastatic prostate cancers (4,8). Recent studies further suggest these two alterations may co-exist in prostate cancer (25). To directly assess the collaborative role of these alterations in prostate tumorigenesis, we generated We then continued our analysis of aged Pten L/L :PB-Cre4 and H11 Met/ϩ /Pten L/L :PB-Cre4 mice up to 24 months of age. We observed that Pten L/L :PB-Cre4 mice develop intracystic carcinomas between 4 and 10 months of age and adenocarcinoma and invasive carcinomas after 10 months ( Table 1). The representative images show corresponding pathologic changes, with features typical of prostatic adenocarcinomas and invasive car-cinomas as reported previously (26) (Fig. 2, E1-E3). In contrast, H11 Met/ϩ /Pten L/L :PB-Cre4 mice showed more aggressive tumor phenotypes than Pten L/L :PB-Cre4 littermates. Comparison of the pathologies of Pten L/L :PB-Cre4 and H11 Met/ϩ / Pten L/L :PB-Cre4 mice revealed an overall more invasive tumor phenotype in the latter (Fig. 2, E versus F). In addition to prostatic adenocarcinomas and invasive carcinomas (Fig. 2, F1-F3), we also observed pathological changes that are similar to prostatic sarcomatoid carcinomas as well as features of an epithelial-mesenchymal transition (EMT) indicating nuclear atypia, a polygonal cell pattern, and pleomorphism (Fig. 2, F3 and F3Ј). A significant increase in MET staining (Fig. 2H1) was observed in tumor lesions of the compound mice. Elevated staining of phospho-Met and phospho-Erk was also observed in adjacent sections of tumor tissues isolated from the compound mice compared with those from Pten L/L :PB-Cre4 only mice (see  Fig. S1C). We did not observe any significant difference in the expression of AR, CK8, and E-cadherin between the above two groups of mice (Fig. 2, G2-G4 and H2-H4). Samples from both Pten L/L :PB-Cre4 and H11 Met/ϩ /Pten L/L :PB-Cre4 were nega-

Conditional expression of Met enhances tumor aggressiveness and induces an epithelial-to-mesenchymal transition in prostate tumors
Scrutiny of H11 Met/ϩ /Pten L/L :PB-Cre4 compound mice revealed an aggressive tumor phenotype with sarcomatoid carcinoma development that did not occur in prostatic lesions of the Pten L/L : PB-Cre4 mice. Representative images from 12-month-old H11 Met/ϩ /Pten L/L :PB-Cre4 compound mice show poorly differentiated carcinomas with areas of invasion, where the epithelial tumor cells have permeated the basement membrane into the surrounding tissue (Fig. 3, A and A1). Cells located at sites of invasion maintain a columnar epithelial shape and some regions of pseudostratified epithelial layers (Fig. 3A1, arrows). A transition from adenocarcinoma and invasive carcinoma lesions to pathology resembling sarcomatoid carcinomas can be observed. Sarcomatoid carcinoma was classified as a biphasic malignant neoplasm, which is frequently observed during the process of EMT (27)(28)(29). We observed spindle-like tumor cells (Fig. 3A2, arrows), tumor cells with a multitude of mitotic figures (Fig. 3A3, arrows), and haphazard acini and lobules of pleomorphic cells (Fig. 3A4), indicating that the above lesions possess mesenchymal morphology and highly proliferative and invasive features.
Observation of the co-occurring prostatic adenocarcinoma, invasive carcinoma, and sarcomatoid carcinoma in the prostate of H11 Met/ϩ /Pten L/L :PB-Cre4 is new and has not been observed in Pten L/L :PB-Cre4 mice. It suggests an important role of Met in promoting tumor progression. To further characterize these lesions, we performed co-immunofluorescent assays to assess the cellular properties of the various regions within the tumor lesions, which include poorly differentiated and invasive carcinomas (Fig. 3, B1-B1Ј), sarcomatoid carcinomas (Fig. 3, D1-D1Ј), and the transition between these two phenotypes (Fig. 3, C1-C1Ј). Tumor cells in adenocarcinoma regions appeared positively stained for CK8, a prostatic luminal epithelial cell marker, and negatively stained for vimentin (Vim), a stromal cell marker (Fig. 3, B2-B4Ј). Within EMT "transition" areas ( Fig. 3, C1-C1Ј), the majority of spindle-like tumor cells were immunoreactive for Vim, but not for the luminal cell marker CK8. Intriguingly, scattered tumor cells revealed double-positive staining for CK8 and Vim (Fig. 3, C4 -C4Ј). Moreover, in sarcomatoid lesions, large, polygonal-shaped cells with little cytoplasm and broad pleomorphic nuclei (Fig. 3, D1-D1Ј) showed positive staining for both CK8 and Vim (Fig. 3, D2-D4).
Using IHC approaches, we further assessed the cellular properties of sarcomatoid tumor cells (Fig. 3E1). The majority of tumor cells showed positive staining with the AR and CK8 (Fig.  3, E2 and E3) but not E-cadherin (Fig. 3E4). Positive staining of Vim appeared in the tumor cells. These expression patterns are consistent with the above co-immunofluorescent experiments and suggest that the process of EMT has occurred in those cells. Additionally, we also examined Ki67 expression and observed significant Ki67-positive cells in sarcomatoid tumor areas, demonstrating the highly proliferative feature of sarcomatoid carcinoma cells (Fig. 3E6). Development of EMT and sarcomatoid tumor lesions in the prostate of H11 Met/ϩ /Pten L/L :PB-Cre4 compound mice provides a direct line of evidence of the promotional role of Met in prostate cancer progression.
It has been shown that Pten L/L :PB-Cre4 mice develop metastatic diseases in the lung and lymphoid nodes (30). Given the more aggressive tumor phenotype seen in H11 Met/ϩ /Pten L/L : PB-Cre4 compound mice, we systematically examined the mice for the presence of metastases during this investigation. We observed prostate cancer metastasis in both Pten L/L :PB-Cre4 and H11 Met/ϩ /Pten L/L :PB-Cre4 mice after 10 months of age ( Table 1). Five of eight H11 Met/ϩ /Pten L/L :PB-Cre4 mice (62.5%) showed metastatic lesions, but only one of eight Pten L/L :PB-Cre4 mice (12.5%) revealed lung and lymph node metastasis ( Table 1). H11 Met/ϩ /Pten L/L :PB-Cre4 mice showed metastatic lesions in lungs and periprostatic lymph nodes (Fig. 4). Histopathological analysis of the lung tissues confirmed the presence of distal metastasis in H11 Met/ϩ /Pten L/L :PB-Cre4 mice, showing circumscribed nodules within the lung parenchyma (Fig. 4,  A and A1). The metastatic foci in the lung were composed of solid nests (poorly differentiated; Fig. 4A1). Histological section of the lymph node demonstrated partial replacement of the cortex by metastatic adenocarcinoma. The lymph node metastasis showed prominent lumen formation (Fig. 4B1). The nuclei displayed a moderate degree of polymorphism, and cytoplasmic vacuoles were present in a subset of the tumor cells. Additionally, IHC analyses of the metastatic tumor cells showed positive staining for AR and Met (Fig. 4, A3-A4 and B3-B4).

Investigation of transcriptional profiles that contribute to prostate cancer progression and metastasis
To determine the molecular mechanisms underlying earlyonset Met-mediated tumor development and progression, we performed RNA-Seq approaches to search for the alterations

Conditional expression of Met increases cellular proliferation, migration, and induction of EMT-associated gene expression
Development of EMT and sarcomatoid carcinomas in the prostate of H11 Met/ϩ /Pten L/L :PB-Cre4 mice suggests a promotional role of Met in cell proliferation, mobility, and migration (60). To test our hypothesis, we performed a set of proof-inprinciple experiments using mouse embryonic fibroblasts (MEFs) that were prepared from Pten L/L , Pten L/L :CMVCreER ϩ , and H11 Met/ϩ /Pten L/L :CMVCreER ϩ embryos (see "Materials and methods"). Using in vitro cell-wounding assays, we directly assessed the effect of Met expression in cell mobility and migration. MEFs of the various genotypes were cultured to 90% confluence and then wounded by a single scratch as described previously (61) and maintained in serum-free medium either in the presence or absence of HGF for 12 h. Images captured immediately after cell wounding demonstrated equal sized scratches across different genotypes (Fig. 6, A1-A6). Following 12 h of wound healing, significant differences in the wound area were visually evident between the various genotypes (Fig. 6, B1-B6).
Whereas Pten L/L :CMVCreER ϩ and Pten L/L control MEFs exhibited slight migration toward the wound, MEFs from H11 Met/ϩ /Pten L/L :CMVCreER ϩ embryos (Fig. 6, B5-B6) demonstrated more closure of the wound, indicative of an increased ability to migrate. Whereas no significant difference was detected between the samples cultured in the absence or presence of HGF, we did observed a slight increase in wound healing from the H11 Met/ϩ /Pten L/L :CMVCreER ϩ MEFs in the presence of HGF, but not in other samples (Fig. 6C). In this study, we also assessed the proliferative ability of the above MEFs using MTS assays. Although, in agreement with previous studies (30), deletion of Pten increases cellular proliferation in MEFs (Fig. 6D, blue line), conditional expression of Met in combination with Pten deletion further enhances cellular proliferation (Fig. 6D, red line). Using qRT-PCR approaches, we examined the expression of Met, Fn1, and Cdh2 in MEFs within three different genotypes. We observed increased expression of Met, as well as Fn1 and Cdh2, in H11 Met/ϩ /Pten L/L :CMVCreER ϩ MEFs compared with both Pten L/L :CMVCreER ϩ and Pten L/L MEFs (Fig. 6D). Taken together, the above results demonstrate a promotional role of Met in cellular migration and proliferation, which is consistent with the aggressive tumor phenotype with EMT features as observed in our mouse models.

Discussion
Emerging evidence from basic, translational, and clinical studies has shown the significance of the HGF/Met signaling pathway in prostate cancer progression and CRPC development (62). Up-regulation of c-Met expression has been observed in a majority of advanced and metastatic prostate cancer lesions (6, 8 -11). However, the biological role of Met in oncogenic transformation and prostate cancer initiation has not been investigated using biologically relevant models. In this study, we developed a novel mouse model, H11 Met/ϩ :PB-Cre4 mice, where expression of the mouse Met gene is specifically activated in prostatic luminal epithelial cells through Cre-LoxP-mediated recombination. We observed mouse prostatic intraepithelial neoplasia development in H11 Met/ϩ :PB-Cre4

The role of HGF-Met in prostate tumorigenesis
mice following the administration of HGF but not in control mice that also received HGF treatments. These results represent the first line of evidence directly demonstrating that the activation of the HGF/Met signaling axis can initiate oncogenic transformation and PIN formation in the mouse prostate. In this study, we did not observe more severe pathologic changes in H11 Met/ϩ :PB-Cre4 mice, suggesting that the activation of the HGF/Met axis alone is not sufficient to induce PIN lesions to progress to prostate cancer. Although the precise mechanisms for the above observation are currently unclear, other oncogenic hits may be required in collaboratively enhancing Metinduced tumor formation in the mouse prostate. In addition, low and inconsistent levels of HGF have been reported in mice (63). Therefore, the H11 Met/ϩ :PB-Cre4 mice will be an experimental tool for further investigating the biological role of Met and other potential hits in prostate cancer initiation.
Multiple lines of evidence have shown the important roles of Met and phosphatidylinositol 3-kinase signaling pathways in

The role of HGF-Met in prostate tumorigenesis
prostate cancer progression and metastasis (3). However, the combinatorial effect of these two pathways in prostate tumorigenesis has not been fully evaluated using the biologically relevant mouse model. In this study, we directly addressed this question using newly generated H11 Met/ϩ /Pten L/L :PB-Cre4 mice. We observed the development of prostatic invasive carcinomas and metastatic diseases in lung and lymph node tissues in Pten L/L :PB-Cre4 mice as reported previously (30). Intriguingly, H11 Met/ϩ /Pten L/L :PB-Cre4 littermates exhibited more aggressive tumor phenotypes in this study (Table 1). In addition to an accelerated HGPIN and prostatic adenocarcinoma development, H11 Met/ϩ /Pten L/L :PB-Cre4 compound mice also showed dominant EMT and sarcomatoid carcinoma lesions with invasive carcinomas. Increased metastatic diseases in lungs and lymph nodes at earlier ages were also revealed in the compound mice compared with Pten null mice. All of these data support a promotional role of Met in prostate cancer pro-gression and metastasis. It should be noted that Pten L/L :PB-Cre4 mice in this study developed prostate tumors relatively more slowly than those in the previous report (30). Actually, our above observation on Pten L/L :PB-Cre4 mice was in agreement with a few other studies (26,64), although the precise reasons for the difference is not clear.
In  To further understand the molecular mechanism underlying Met-mediated tumor progression and metastasis, we examined the transcriptional profile in prostate tumor tissues isolated from both Pten L/L :PB-Cre4 and H11 Met/ϩ /Pten L/L :PB-Cre4 mice using RNA-Seq approaches. Increased expression of mesenchymal markers, such as vimentin, N-cadherin, fibronectin 1, and SPP1, was detected in tumor samples isolated from H11 Met/ϩ /Pten L/L :PB-Cre4 mice compared with those from Pten L/L :PB-Cre4 littermates. Identification of a subset of genes related to tumor transdifferentiation and EMT in the samples of H11 Met/ϩ /Pten L/L :PB-Cre4 mice is intriguing and provides a molecular basis for transgenic Met-induced tumor progression and metastasis in the compound mice. EMT has mostly been studied with regard to the acquisition of invasive characteristics and metastatic potential (60). Determining the molecular mechanisms by which transgenic Met increases the expression of genes that promote EMT and tumor progression is important and should be carried out in the future.
A significant challenge within the field of prostate cancer has been to develop biologically relevant models for studying metastatic bone lesions (65). The HGF-Met signaling axis is known to be important to bone remodeling; both the ligand and receptor are found to be expressed in the bone marrow and can induce cellular proliferation of both osteoclasts and osteoblasts (66,67). Furthermore, an increase in expression of both the Met receptor and the HGF ligand has been observed at sites of prostate cancer bone metastasis, suggesting that this pathway may be active during bone metastasis (8). Despite the evidence indicating that c-Met expression is associated with bone metastases in human prostate cancer, we were only able to detect metastasis to the lung and lymphoid nodes in H11 Met/ϩ /Pten L/L :PB-Cre4 compound mice as reported in Pten L/L :PB-Cre4 mice (30). Although the reasons why prostate tumor cells with transgenic Met expression are unable to further advance to aggressive disease with bone metastasis in the above compound mice are unclear, data generated from this study have lead us to pursue a few new experiments. Increased activation of Met receptor by the HGF ligand may be necessary to achieve bone metastases using the new mouse model with both transgenic HGF and Met expression. Alternatively, modification of other signaling axes may be necessary for the dissemination of prostate cancer cells to the bones. In support of this hypothesis, a recent clinical trial using cabozantinib, a dual inhibitor of c-Met and VEGFR2, indicated a resolution of bone metastases in 12% of men treated (68). Therefore, development of new mouse models with additional genetic changes in addition to Met activation may be considered in the future.
In this study, we have developed a novel and biologically relevant model for examining the role of c-Met in prostate tumorigenesis. We have shown that c-Met can enhance PTEN-mediated prostate tumor progression by inducing an EMT tumor phenotype and increasing the incidence of metastasis. Given the importance of c-Met in human prostate cancer, we aim to use this model to understand c-Met signaling and its effects during prostate cancer development and progression.

Generation of the Met transgene target vector
To generate the LSL-Met transgenic mouse line, we used integrase-mediated transgenesis technology (19). In brief, mouse Met cDNA was subcloned into the pB378 vector that contains an attB recombination site. A loxP-PGK-Neomycin-STOP-loxP cassette was inserted between the CMV early enhancer/chicken ␤-actin (CAG) promoter and a FLAGtagged mouse Met coding sequence followed by a polyadenylation signal (Fig. 1A). The DNA was purified and microinjected along with C31 integrase mRNA into zygotic pro-nuclei of an FVB mouse that contains an attP docking site at the H11 locus. The above targeted mice were screened by mouse tail tissue genomic PCR using P1 (5Ј-AGCGCATCGCCTTCTATCGC-CTTC-3Ј) and P3 (5Ј-AAACAATCTGGGTGTTCC-3Ј) primers and further confirmed by DNA sequencing.

Mouse breeding and genotyping
The founder mice were bred with WT C57Bl6/J, and progenies were genotyped to confirm the presence of the transgene. To generate conditional Met transgenic mice, the LSL-Met transgenic mice (H11 Met/ϩ ) were intercrossed with the PB-Cre4 strain, carrying the Cre transgene under the control of a modified probasin promoter (ARR2PB) (20). Mice homozygous for floxed Pten, Pten L/L , were obtained from the Jackson Laboratory (Bar Harbor, ME; strain 004597). All animals used in this study were on a C57BL/6 background, and all experiments were performed in accordance with animal care guidelines approved by the institutional animal care and use committee at Beckman Research Institute and City of Hope.
For genotyping, mouse tail tips were incubated in lysis buffer (catalog no. 102-T, VIAGEN Biotech, Los Angeles, CA) for genomic DNA. The conditional expression of H11 Met/ϩ was detected with the forward 5Ј-AGCGCATCGCCTTCTATCG-CCTTC-3Ј and reverse 5Ј-AAACAATCTGGGTGTTCC-3Ј primers. PCR was performed as follows: 5 min at 94°C and then 34 cycles of 94°C for 30 s, 62°C for 30 s, and 72°C for 70 s, followed by a final step at 72°C for 5 min. For Pten allele, the forward 5Ј-TCCCAGAGTTCATACCAGGA-3Ј and reverse

Mouse procedures
For HGF injection, recombinant human HGF (294-HG/CF, R&D Systems, Minneapolis, MN) was dissolved in sterile PBS at 100 g/ml and stored at Ϫ80°C. Three doses of HGF were given to 6-month-old H11 Met/ϩ :PB-Cre4 mice at 0.5 g/g body weight via intraperitoneal injection for 3 consecutive weeks. Tissues were harvested 120 days after the initial HGF injection.

Histological analyses and immunostaining
Mouse tissues were fixed and processed as described in our previous study (72). For histological analysis, 5-m serial sections were processed from Clearify (American MasterTech (Lodi, CA)) to water through a decreasing ethanol gradient, stained with 5% (w/v) Harris hematoxylin and eosin, and processed back to Clearify through an increasing ethanol gradient.
For immunofluorescent staining, mouse tissues were cut into 5-m sections and then boiled in 0.01 M citrate buffer (pH 6.0) for 20 min after redehydration, blocked in 5% normal goat serum for 30 min, and incubated with primary antibodies diluted in 1% normal goat serum at 4°C overnight. Slides were washed in PBS and then incubated with fluorescence-conjugated secondary antibodies for 1 h and mounted with VECTASHIELD Mounting Medium with 4Ј,6-diamidino-2-phenylindole (H-1200, Vector Laboratories).

Mouse embryonic fibroblasts, MTS cell viability assay, and wound-healing assay
H11 Met/ϩ /Pten L/L females were mated with Pten L/L :CMV CreER ϩ males. Pregnant females received two intraperitoneal injections of tamoxifen (Sigma) at E11.5 and E12.5 of 2 mg/25 g body weight and were sacrificed at E13.5. The embryos were isolated in cold PBS and then digested with 0.25% trypsin for 30 min at 37°C, followed by the addition of Dulbecco's modified Eagle's medium containing 10% FBS and 1% penicillin/streptomycin. The cells were directly plated into 6-well plates and allowed to adhere overnight. To determine the genotypes, embryo yolk sacs isolated during the dissection were digested, and genomic DNA was extracted (73,74) and used for genotyping with appropriate primers as mentioned above. For CMVCreER, the forward 5Ј-TTGCCTGCATTACCGGTCGATGCA-3Ј and reverse 5Ј-GATCCTGGCAATTTCGGCTAT-3Ј primers were used with the program listed as follows: 94°C for 5 min and then 29 cycles of 94°C for 20 s, 64°C for 30 s, and 72°C for 25 s, followed by 72°C for 2 min.
For the MTS cell viability assay, ϳ2000 cells/well were plated in 96-well plate and then harvested at different time points. Cell growth assays were carried out using an MTS cell proliferation assay kit (G5430, Promega, Madison, WI). Cell numbers were determined by absorbance at 490 nm, as suggested by the manufacturer.
For the wound-healing assay, 2 ϫ 10 5 cells/well were seeded into a 12-well plate and cultured in the absence or presence of 10 nM recombinant human HGF to 90% confluence. The cells were then starved with 0.1% FBS overnight and scratched with The role of HGF-Met in prostate tumorigenesis a sterile 200-l tip to form a straight wound. The cells were washed three times with PBS and cultured in normal medium for an additional 24 h. A Nikon ECLIPSE E800 microscope was used to measure the wound closure. Images were recorded at 0, 12, and 24 h after wounding with QImaging RETIGA EXi camera and QCapture software (QImaging, Surrey, Canada). The distances invaded by the cells at the front of the wound were measured from the control and the experimental samples.

RNA isolation, RNA-Seq, and qRT-PCR
RNA samples were isolated from age-matched mice of different genotypes. The prostate tissues were homogenized in RNA-Bee (TEL-TEST, Inc., Friendswood, TX), and total RNA was isolated as recommended by the manufacturer. The purified RNA libraries were then sequenced using the Illumina HiSeq 2000 at the City of Hope Integrative Genomics Core.
RT was carried out as described in our previous report (75). For quantitative PCR, cDNA samples were mixed with SYBR GreenER qPCR Super Mix Universal (11762, Invitrogen) and specific primers, and quantitative PCR was performed according to the manufacturer's protocol. Relative mRNA levels were calculated by the ⌬⌬C(T) method (76)

Statistical analyses
Data are shown as the mean Ϯ S.D. Differences between groups were examined by two-tailed Student's t test or twoway analysis of variance for comparisons among multiple groups. For all analyses, p Ͻ 0.05 was considered statistically significant.