It is generally agreed that ERa is expressed mainly in the stromal compartment, but not in the epithelial compartment of prostate. However, results from stromal-epithelial tissue recombination experiments gave distinct results as to whether epithelial ERa or stromal ERa plays a role in the estrogen-mediated responses in prostatic tissue. The experiment, in which prostatic compartments were reconstituted by tissue recombination and transplanted under the kidney capsule, concluded that both epithelial and stromal ERa are required for estrogen-mediated squamous metaplasia;yet, the field debated that the stromal or epithelial cells isolated from the anterior prostate, which has a different developmental origin from ventral prostate and dorsalateral prostate of animals. In addition to prostate development, it has been reported that early exposure of E2 will lead to imprinting effects of mouse prostates to develop squamous metaplasia (SQM). Furthermore, a growing body of evidence indicated that estrogen plus androgen will stimulate the carcinogenesis of prostate in recombinant experiments and in intact animals. Interestingly, ERa, but not ER?, is critical for E2-imprinting squamous metaplasia and carcinogenesis using conventional ERaKO and ER?KO mice as model or material source to conduct experiments. The conventional total ERa knockout (ERaKO) mice may generate compound effects and sometimes it is unclear whether the observed phenotypes on a given tissue is due to the ERa function in the given tissue or due to the defect of ERa function in other tissues. Therefore, it is important to establish a better material source, or a better animal model to re-examine the role of stromal and epithelial ERa in prostatic homeostasis and carcinogenesis. We decided to generate the tissue specific KO mice by using the Cre-LoxP strategy to elucidate the respective roles of epithelial and stromal ERa in prostatic homeostasis and carcinogenesis. The main goal of this proposal is to obtain a better understanding of the roles of ERa in prostatic biology, and to identify the potential ERa target genes in the prostatic tissue. To achieve these goals, we will pursue the following Specific Aims.
Aim 1 will use Cre-LoxP strategy to generate mice with epithelial-ERaKO and to determine whether epithelial ERaKO will affect prostate development and estrogen imprinting effect.
Aim 2 will generate mice with prostate stromal-ERa knockout and investigate prostate development and the estrogen imprinting effects.
Aim 3 will establish mouse prostate cancer models with ERa knockout and investigate prostate tumorigenesis and tumor progression.
Aim 4 will identify and examine how ERa regulates the expression of the stromal factors and target genes that may mediate the estrogenic effects on aberrant prostate epithelial growth, squamous metaplasia and cancerous transformation.
We hypothesize that estrogen receptor alpha (ERa), a female hormone receptor, plays important roles in male prostate homeostasis and the aberrant signaling mediated by ERa may contribute to a higher incidence of prostate cancer. Several in vitro and in vivo strategies will be used to investigate and validate ERa functions and its downstream signals. The accomplishment of the project will help us gain insights on the role of ERa in prostate homeostasis and cancerous transformation, and the results could also lead to developing new alternative treatments for human prostate cancer in the future.
|Yeh, Chiuan-Ren; Slavin, Spencer; Da, Jun et al. (2016) Estrogen receptor ? in cancer associated fibroblasts suppresses prostate cancer invasion via reducing CCL5, IL6 and macrophage infiltration in the tumor microenvironment. Mol Cancer 15:7|
|Slavin, Spencer; Yeh, Chiuan-Ren; Da, Jun et al. (2014) Estrogen receptor ? in cancer-associated fibroblasts suppresses prostate cancer invasion via modulation of thrombospondin 2 and matrix metalloproteinase 3. Carcinogenesis 35:1301-9|
|Vitkus, Spencer; Yeh, Chiuan-Ren; Lin, Hsiu-Hsia et al. (2013) Distinct function of estrogen receptor ? in smooth muscle and fibroblast cells in prostate development. Mol Endocrinol 27:38-49|
|Hsu, Iawen; Vitkus, Spencer; Da, Jun et al. (2013) Role of oestrogen receptors in bladder cancer development. Nat Rev Urol 10:317-26|
|Chen, Ming; Yeh, Chiuan-Ren; Shyr, Chih-Rong et al. (2012) Reduced prostate branching morphogenesis in stromal fibroblast, but not in epithelial, estrogen receptor ? knockout mice. Asian J Androl 14:546-55|
|Chen, Ming; Yeh, Chiuan-Ren; Chang, Hong-Chiang et al. (2012) Loss of epithelial oestrogen receptor ? inhibits oestrogen-stimulated prostate proliferation and squamous metaplasia via in vivo tissue selective knockout models. J Pathol 226:17-27|
|Yu, Shengqiang; Zhang, Caixia; Lin, Chiu-Chun et al. (2011) Altered prostate epithelial development and IGF-1 signal in mice lacking the androgen receptor in stromal smooth muscle cells. Prostate 71:517-24|