Project description:AR is tightly regulated by many transcriptional cofactors, including key pioneer factor such as FOXA1 and GATA2. While FOXA1 was recently shown to be able to redistribute AR across the genome, how GATA2 regulates AR cistrome has not been carefully investigated. Here, we report that, unlike FOXA1, GATA2 is unable to reprogram AR, but instead it enhances AR program by inducing AR expression and augmenting AR co-occupancy, thereby acting as a pure AR coactivator, rather than a pioneer factor. On the other hand, AR co-occupancy enhances both GATA2 and FOXA1 binding on the chromatin, forming a positive feedback loop. Importantly, we found that FOXA1 is also capable of reprogramming GATA2 by recruiting GATA2 from GATA motif to FKHD-containing regions, being analogous to its pioneering effect on AR signaling. By contrast, GATA2 simply acts as a co-activator of FOXA1 with a lack of pioneering ability. ChIP_Seq examination of AR, FoxA1 and GATA2 binding sites in LNCaP and DU145 cells

Project description:AR is tightly regulated by many transcriptional cofactors, including key pioneer factor such as FOXA1 and GATA2. While FOXA1 was recently shown to be able to redistribute AR across the genome, how GATA2 regulates AR cistrome has not been carefully investigated. Here, we report that, unlike FOXA1, GATA2 is unable to reprogram AR, but instead it enhances AR program by inducing AR expression and augmenting AR co-occupancy, thereby acting as a pure AR coactivator, rather than a pioneer factor. On the other hand, AR co-occupancy enhances both GATA2 and FOXA1 binding on the chromatin, forming a positive feedback loop. Importantly, we found that FOXA1 is also capable of reprogramming GATA2 by recruiting GATA2 from GATA motif to FKHD-containing regions, being analogous to its pioneering effect on AR signaling. By contrast, GATA2 simply acts as a co-activator of FOXA1 with a lack of pioneering ability. genetic_modification_design

Project description:AR is tightly regulated by many transcriptional cofactors, including key pioneer factor such as FOXA1 and GATA2. While FOXA1 was recently shown to be able to redistribute AR across the genome, how GATA2 regulates AR cistrome has not been carefully investigated. Here, we report that, unlike FOXA1, GATA2 is unable to reprogram AR, but instead it enhances AR program by inducing AR expression and augmenting AR co-occupancy, thereby acting as a pure AR coactivator, rather than a pioneer factor. On the other hand, AR co-occupancy enhances both GATA2 and FOXA1 binding on the chromatin, forming a positive feedback loop. Importantly, we found that FOXA1 is also capable of reprogramming GATA2 by recruiting GATA2 from GATA motif to FKHD-containing regions, being analogous to its pioneering effect on AR signaling. By contrast, GATA2 simply acts as a co-activator of FOXA1 with a lack of pioneering ability.

Project description:AR is tightly regulated by many transcriptional cofactors, including key pioneer factor such as FOXA1 and GATA2. While FOXA1 was recently shown to be able to redistribute AR across the genome, how GATA2 regulates AR cistrome has not been carefully investigated. Here, we report that, unlike FOXA1, GATA2 is unable to reprogram AR, but instead it enhances AR program by inducing AR expression and augmenting AR co-occupancy, thereby acting as a pure AR coactivator, rather than a pioneer factor. On the other hand, AR co-occupancy enhances both GATA2 and FOXA1 binding on the chromatin, forming a positive feedback loop. Importantly, we found that FOXA1 is also capable of reprogramming GATA2 by recruiting GATA2 from GATA motif to FKHD-containing regions, being analogous to its pioneering effect on AR signaling. By contrast, GATA2 simply acts as a co-activator of FOXA1 with a lack of pioneering ability.

Project description:Androgen receptor (AR) is a key player in prostate cancer development and progression. Here we applied immunoprecipitation mass spectrometry of endogenous AR in LNCaP cells to identify components of the AR transcriptional complex. In total, 66 known and novel AR interactors were identified in the presence of synthetic androgen, most of which were critical for AR-driven prostate cancer cell proliferation. A subset of AR interactors required for LNCaP proliferation were profiled using chromatin immunoprecipitation assays followed by sequencing, identifying distinct genomic subcomplexes of AR interaction partners. Interestingly, three major subgroups of genomic subcomplexes were identified, where selective gain of function for AR genomic action in tumorigenesis was found, dictated by FOXA1 and HOXB13. In summary, by combining proteomic and genomic approaches we reveal subclasses of AR transcriptional complexes, differentiating normal AR behavior from the oncogenic state. In this process, the expression of AR interactors has key roles by reprogramming the AR cistrome and interactome in a genomic location-specific manner.

Project description:To identify potential cofactors of HOXB13 in suppressing lipogenic programs in prostate cancer cells, we performed tandem affinity purification followed by mass spectrometry analysis of WT and G84E HOXB13 expressed in LNCaP cells. Out of the HOXB13-enriched proteins are previously reported interactors such as AR and its cofactors FOXA1, GATA2, and NKX3. However, these interactions were not disrupted by G84E as compared to WT HOXB13. Interestingly, we found strong interactions of HOXB13 with HDAC1/3 and their corepressors NCoR1/2 and TBL1X. Notably, these interactions were drastically reduced by G84E mutation.

Project description:GATA2 and FOXA1 are pioneering factors for Androgen Receptor (AR) in prostate cancer cells. Less is known about their role in benign epithelial prostate cells. We investigated if they had the ability to induce differentiation in an undifferentiated prostatic context. Benign basal-like prostate epithelial cells 957E/hTERT-AR cells (a gift from John T. Isaacs lab, Johns Hopkins, MD, USA) were transduced with LentiORF RFP control lentiviral particles. The 957E/hTERT-AR-RFP cells were then transduced with GATA2 and FOXA1 lentiviral particles, and we called the new cell lines hTERT/AR-GATA2 and hTERT/AR-FOXA1, respectively. hTERT/AR-GATA2 is a stable selected cell line and treated with 1 nM anabolic steroids, R1881, or ethanol (ET-OH) for 48 hrs. 957E/hTERT/AR-FOXA1 is a transient cell line, because FOXA1 protein is quickly lost. Twenty four hours post transduction with FOXA1 lentivral particles, 1 nM androgen R1881 or ethanol (ET-OH) were added at time for medium exchange and further treated for 24 hours. GATA-2 and FOXA1 ability to induce differentiation was assessed.

Project description:Amplification of the androgen receptor (AR) locus is the most frequent alteration in metastatic treatment resistant prostate cancer. Recently it was discovered that an enhancer of the AR is co-amplified with the AR gene body and contributes to increased AR transcription and resistance to androgen deprivation therapy. However, the mechanism of enhancer activation in advanced disease is unknown. Here, we used functional genetic screening to identify transcription factors that bind to the AR enhancer and are required for enhancer mediated AR transcription. We validated binding of the transcription factors, HOXB13, GATA2, and TFAP2C in patient derived xenografts and demonstrated differential effects on features associated with active chromatin state including H3K27ac, DNA accessibility, and enhancer-promoter interaction frequency. Interestingly, the AR enhancer belongs to a set of regulatory elements that requires HOXB13 to maintain FOXA1 binding, uncovering a novel role for HOXB13 in castration-resistant prostate cancer. This work provides a framework to functionally identify trans-acting factors required for activation of disease related noncoding regulatory elements.

Project description:Amplification of the androgen receptor (AR) locus is the most frequent alteration in metastatic treatment resistant prostate cancer. Recently it was discovered that an enhancer of the AR is co-amplified with the AR gene body and contributes to increased AR transcription and resistance to androgen deprivation therapy. However, the mechanism of enhancer activation in advanced disease is unknown. Here, we used functional genetic screening to identify transcription factors that bind to the AR enhancer and are required for enhancer mediated AR transcription. We validated binding of the transcription factors, HOXB13, GATA2, and TFAP2C in patient derived xenografts and demonstrated differential effects on features associated with active chromatin state including H3K27ac, DNA accessibility, and enhancer-promoter interaction frequency. Interestingly, the AR enhancer belongs to a set of regulatory elements that requires HOXB13 to maintain FOXA1 binding, uncovering a novel role for HOXB13 in castration-resistant prostate cancer. This work provides a framework to functionally identify trans-acting factors required for activation of disease related noncoding regulatory elements.

Project description:Amplification of the androgen receptor (AR) locus is the most frequent alteration in metastatic treatment resistant prostate cancer. Recently it was discovered that an enhancer of the AR is co-amplified with the AR gene body and contributes to increased AR transcription and resistance to androgen deprivation therapy. However, the mechanism of enhancer activation in advanced disease is unknown. Here, we used functional genetic screening to identify transcription factors that bind to the AR enhancer and are required for enhancer mediated AR transcription. We validated binding of the transcription factors, HOXB13, GATA2, and TFAP2C in patient derived xenografts and demonstrated differential effects on features associated with active chromatin state including H3K27ac, DNA accessibility, and enhancer-promoter interaction frequency. Interestingly, the AR enhancer belongs to a set of regulatory elements that requires HOXB13 to maintain FOXA1 binding, uncovering a novel role for HOXB13 in castration-resistant prostate cancer. This work provides a framework to functionally identify trans-acting factors required for activation of disease related noncoding regulatory elements.