Regulation of E2F-1 gene expression in human breast cancer cells

Ngwenya, Sharon Khethiwe

29 August 2005

17β-Estradiol induces E2F-1 gene expression in ZR-75 and MCF-7 human breast cancer cells. Analysis of the E2F-1 gene promoter in MCF-7 cells previously showed that hormone-induced transactivation required interactions between estrogen receptor α (ERα)/Sp1 bound to upstream GC-rich sites and NFYA bound to downstream CCAAT sites within the -169 to -54 promoter region. This promoter region was also E2-responsive in ERα-positive ZR-75 cells; however, further analysis of the promoter showed that cooperative ERα/Sp1/NFY interactions were not necessary for hormone-induced transactivation in ZR-75 cells. The upstream GC-rich motifs are activated independently by ERα/Sp1 in ZR-75 but not MCF-7 cells, and the downstream CCAAT sites were also E2-responsive. E2 also induced reporter gene activity in ZR-75 cells transfected with an expression plasmid containing the yeast GAL4 DNA binding domain fused to pM-NFYA and a construct containing five tandem GAL4 response elements. Subsequent studies showed that hormonal activation of pE2F-1jm1 and pM-NFYA are dependent on non-genomic pathways in which E2 activates cAMP/protein kinase A. Hormone-dependent regulation of E2F-1 gene expression in ZR-75 and MCF-7 involves different mechanisms, demonstrating the importance of cell context on transactivation pathways, even among ER-positive breast cancer cell lines. TCDD inhibited ERα-mediated responses in MCF-7 and ZR-75 cells. E2- induced E2F-1protein and mRNA levels in MCF-7 and ZR-75 cells and this response was inhibited by TCDD. Constructs containing GC-rich sites alone or in combination with the downstream NFY sites were used in transactivation studies to investigate the mechanism of inhibitory AhR-ERα crosstalk. Although TCDD inhibited E2-induced mRNA, protein and reporter gene actitivity, it was not possible to determine if the inhibitory response was due to limiting ERα protein levels due to proteasome degradation since proteaome inhibitors alone blocke hormone-dependent responses. TCDD also inhibited the cAMP/PKA pathway by inhibiting adenyl cyclase activity. In Drosophila SL-2 cells cotransfected with the GC-rich -169 to -54 region, ERα and Sp1 plasmids E2 induced transactivation in cells cotransfected with AhR/Arnt expression plasmids suggesting that the AhR complex suppressed ERα/Sp1 action. These results demonstrate that TCDD inhibits E2-dependent activation of both non-genomic and genomic pathways of ER-mediated E2F-1 gene expression. 17β-Estradiol induces E2F-1 gene expression in ZR-75 and MCF-7 human breast cancer cells. Analysis of the E2F-1 gene promoter in MCF-7 cells previously showed that hormone-induced transactivation required interactions between estrogen receptor α (ERα)/Sp1 bound to upstream GC-rich sites and NFYA bound to downstream CCAAT sites within the -169 to -54 promoter region. This promoter region was also E2-responsive in ERα-positive ZR-75 cells; however, further analysis of the promoter showed that cooperative ERα/Sp1/NFY interactions were not necessary for hormone-induced transactivation in ZR-75 cells. The upstream GC-rich motifs are activated independently by ERα/Sp1 in ZR-75 but not MCF-7 cells, and the downstream CCAAT sites were also E2-responsive. E2 also induced reporter gene activity in ZR-75 cells transfected with an expression plasmid containing the yeast GAL4 DNA binding domain fused to pM-NFYA and a construct containing five tandem GAL4 response elements. Subsequent studies showed that hormonal activation of pE2F-1jm1 and pM-NFYA are dependent on non-genomic pathways in which E2 activates cAMP/protein kinase A. Hormone-dependent regulation of E2F-1 gene expression in ZR-75 and MCF-7 involves different mechanisms, demonstrating the importance of cell context on transactivation pathways, even among ER-positive breast cancer cell lines. TCDD inhibited ERα-mediated responses in MCF-7 and ZR-75 cells. E2- induced E2F-1protein and mRNA levels in MCF-7 and ZR-75 cells and this response was inhibited by TCDD. Constructs containing GC-rich sites alone or in combination with the downstream NFY sites were used in transactivation studies to investigate the mechanism of inhibitory AhR-ERα crosstalk. Although TCDD inhibited E2-induced mRNA, protein and reporter gene actitivity, it was not possible to determine if the inhibitory response was due to limiting ERα protein levels due to proteasome degradation since proteaome inhibitors alone blocke hormone-dependent responses. TCDD also inhibited the cAMP/PKA pathway by inhibiting adenyl cyclase activity. In Drosophila SL-2 cells cotransfected with the GC-rich -169 to -54 region, ERα and Sp1 plasmids E2 induced transactivation in cells cotransfected with AhR/Arnt expression plasmids suggesting that the AhR complex suppressed ERα/Sp1 action. These results demonstrate that TCDD inhibits E2-dependent activation of both non-genomic and genomic pathways of ER-mediated E2F-1 gene expression.

E2F-1

Breast Cancer

Transcriptional regulation of the pro-apoptotic gene Bnip3 by P65 NF-κB, Histone Deacetylase 1, and E2F-1 in postnatal ventricular myocytes

Shaw, James Alexander

20 August 2009

Apoptotic cell death of cardiac myocytes plays an important pathological role after a myocardial infarction and during heart failure. Apoptotic myocytes are not regenerated because of the restricted ability of terminally differentiated cardiac myocytes to undergo cell division. Because ventricular function is directly related to the number of active muscle cells, the inappropriate loss or premature death of cardiac myocytes results in reduced cardiac performance. Bnip3 was previously identified by Dr. Lorrie Kirshenbaum’s laboratory as a critical mediator of hypoxia-induced apoptosis in the heart. Importantly, his lab established that the cytoprotective actions of NF-κB during hypoxia included the transcriptional repression of Bnip3. However, the mechanism by which NF-κB acted as a transcriptional repressor was undefined. The present work strongly supports the hypothesis that NF-κB-mediated inhibition of Bnip3 transcription is dependent on the recruitment of the corepressor protein HDAC1. Immunoprecipitation experiments revealed that HDAC1 and p65 NF-κB formed protein-protein interactions. ChIP assays demonstrated that HDAC1 and p65 NF-κB associated with the Bnip3 promoter. HDAC1-mediated repression of Bnip3 was lost in cells deficient for p65 NF-κB, and restored upon repletion of p65. A second avenue of investigation described in this work demonstrated that the cell cycle factor E2F-1 directly activated Bnip3 transcription. Earlier work by Dr. Kirshenbaum found that adenovirus-mediated overexpression of E2F-1 in ventricular myocytes induced apoptosis. Herein, it is shown that E2F-1-mediated cell death is largely Bnip3-dependent because functional loss of Bnip3 inhibited E2F-1-induced cell death. Concerning hypoxia, Bnip3 expression is dependent upon the loss of p65/HDAC1-mediated repression, and on the presence of transcriptionally active E2F-1. During hypoxia, overexpression of p65, HDAC1, or Rb, an endogenous inhibitor of E2F-1-dependent transcription, attenuated hypoxia-induced Bnip3 transcription. Based on these findings, future therapies may be designed to repress Bnip3 gene expression after a myocardial infarction, thereby averting cardiac cell death and preserving cardiac function post-infarction.

Bnip3

E2F-1

Apoptosis

Hypoxia

Mitochondria

Myocyte

NF-κB

Cell Culture

HDAC1

Transcriptional regulation of the pro-apoptotic gene Bnip3 by P65 NF-κB, Histone Deacetylase 1, and E2F-1 in postnatal ventricular myocytes

Shaw, James Alexander

20 August 2009

Apoptotic cell death of cardiac myocytes plays an important pathological role after a myocardial infarction and during heart failure. Apoptotic myocytes are not regenerated because of the restricted ability of terminally differentiated cardiac myocytes to undergo cell division. Because ventricular function is directly related to the number of active muscle cells, the inappropriate loss or premature death of cardiac myocytes results in reduced cardiac performance. Bnip3 was previously identified by Dr. Lorrie Kirshenbaum’s laboratory as a critical mediator of hypoxia-induced apoptosis in the heart. Importantly, his lab established that the cytoprotective actions of NF-κB during hypoxia included the transcriptional repression of Bnip3. However, the mechanism by which NF-κB acted as a transcriptional repressor was undefined. The present work strongly supports the hypothesis that NF-κB-mediated inhibition of Bnip3 transcription is dependent on the recruitment of the corepressor protein HDAC1. Immunoprecipitation experiments revealed that HDAC1 and p65 NF-κB formed protein-protein interactions. ChIP assays demonstrated that HDAC1 and p65 NF-κB associated with the Bnip3 promoter. HDAC1-mediated repression of Bnip3 was lost in cells deficient for p65 NF-κB, and restored upon repletion of p65. A second avenue of investigation described in this work demonstrated that the cell cycle factor E2F-1 directly activated Bnip3 transcription. Earlier work by Dr. Kirshenbaum found that adenovirus-mediated overexpression of E2F-1 in ventricular myocytes induced apoptosis. Herein, it is shown that E2F-1-mediated cell death is largely Bnip3-dependent because functional loss of Bnip3 inhibited E2F-1-induced cell death. Concerning hypoxia, Bnip3 expression is dependent upon the loss of p65/HDAC1-mediated repression, and on the presence of transcriptionally active E2F-1. During hypoxia, overexpression of p65, HDAC1, or Rb, an endogenous inhibitor of E2F-1-dependent transcription, attenuated hypoxia-induced Bnip3 transcription. Based on these findings, future therapies may be designed to repress Bnip3 gene expression after a myocardial infarction, thereby averting cardiac cell death and preserving cardiac function post-infarction.

Bnip3

E2F-1

Apoptosis

Hypoxia

Mitochondria

Myocyte

NF-κB

Cell Culture

HDAC1