Poly(ADP-ribose) polymerase upregulates E2F-1 promoter activity and DNA pol alpha expression during early S phase. (73/1403)

E2F-1, a transcription factor implicated in the activation of genes required for S phase such as DNA pol alpha, is regulated by interactions with Rb and by cell-cycle dependent alterations in E2F-1 abundance. We have shown that depletion of poly(ADP-ribose) polymerase (PARP) by antisense RNA expression downregulates pol alpha and E2F-1 expression during early S phase. To examine the role of PARP in the regulation of pol alpha and E2F-1 gene expression, we utilized immortalized mouse fibroblasts derived from wild-type and PARP knockout (PARP-/-) mice as well as PARP-/- cells stably transfected with PARP cDNA [PARP-/-(+PARP)]. After release from serum deprivation, wild-type and PARP-/-(+PARP) cells, but not PARP-/- cells, exhibited a peak of cells in S phase by 16 h and had progressed through the cell cycle by 22 h. Whereas [3H]thymidine incorporation remained negligible in PARP-/- cells, in vivo DNA replication maximized after 18 h in wild-type and PARP-/-(+PARP) cells. To investigate the effect of PARP on E2F-1 promoter activity, a construct containing the E2F-1 gene promoter fused to a luciferase reporter gene was transiently transfected into these cells. E2F-1 promoter activity in control and PARP-/-(+PARP) cells increased eightfold after 9 h, but not in PARP-/- cells. PARP-/- cells did not show the marked induction of E2F-1 expression during early S phase apparent in control and PARP-/-(+PARP) cells. RT - PCR analysis and pol alpha activity assays revealed the presence of pol alpha transcripts and a sixfold increase in activity in both wild-type and PARP-/-(+PARP) cells after 20 h, but not in PARP-/- cells. These results suggest that PARP plays a role in the induction of E2F-1 promoter activity, which then positively regulates both E2F-1 and pol alpha expression, when quiescent cells reenter the cell cycle upon recovery from aphidicolin exposure or removal of serum.  (+info)

E2F activates late-G1 events but cannot replace E1A in inducing S phase in terminally differentiated skeletal muscle cells. (74/1403)

We have previously shown that the adenovirus E1A oncogene can reactivate the cell cycle in terminally differentiated cells. Current models imply that much or all of this E1A activity is mediated by the release of the E2F transcription factors from pocket-protein control. In contrast, we show here that overexpression of E2F-1, E2F-2 and E2F-4, or a chimeric E2F-4 tethered to a nuclear localization signal cannot reactivate postmitotic skeletal muscle cells (myotubes). This is not due to lack of transcriptional activity, as demonstrated on both a reporter construct and a number of endogenous target genes. Although cyclin E was strongly overexpressed in E2F-transduced myotubes, it lacked associated kinase activity, possibly explaining the inability of the myotubes to enter S phase and accumulate cyclin A. Although E2F is not sufficient to trigger DNA synthesis in myotubes, its activity is necessary even in the presence of E1A, as dominant-negative DP-1 mutants inhibit E1A-mediated cell cycle reentry. Our data show that, to reactivate myotubes, E1A must exert other functions, in addition to releasing E2F. They also establish mouse myotubes as an experimental system uniquely suited to study the most direct E2F functions in the absence of downstream cell cycle effects.  (+info)

Control of E2F activity by p21Waf1/Cip1. (75/1403)

Cyclin-dependent kinase inhibitors (cdkis), such as p21, are believed to control proliferation through an ability to function as stoichiometric antagonists of cyclin-dependent kinases (cdks). The p21 gene is a direct transcriptional target for the p53 protein, and its activation is likely to be important in effecting the p53 response. It is widely accepted that p21 can influence cell cycle progression by controlling the activity of cdks that act on the retinoblastoma tumour suppressor protein (pRb) which, in a hypophosphorylated state, associates with E2F transcription factors to prevent the activation of genes required for progression into S phase. Phosphorylation of pRb by G1 cdk complexes releases E2F and thereby enables progress through the cell cycle. Here, we describe results which suggest a p21-dependent mechanism that facilitates the regulation of E2F through a pathway that is independent of the cdk control of pRb activity. As p21 can associate with E2F subunits, it is possible that these effects are exerted through a complex with E2F. Furthermore, we find that p21 can regulate transcription in vitro. The results suggest that p21 may control E2F activity through a pathway that acts independently of pRb.  (+info)

Cdk phosphorylation triggers sequential intramolecular interactions that progressively block Rb functions as cells move through G1. (76/1403)

We present evidence that phosphorylation of the C-terminal region of Rb by Cdk4/6 initiates successive intramolecular interactions between the C-terminal region and the central pocket. The initial interaction displaces histone deacetylase from the pocket, blocking active transcriptional repression by Rb. This facilitates a second interaction that leads to phosphorylation of the pocket by Cdk2 and disruption of pocket structure. These intramolecular interactions provide a molecular basis for sequential phosphorylation of Rb by Cdk4/6 and Cdk2. Cdk4/6 is activated early in G1, blocking active repression by Rb. However, it is not until near the end of G1, when cyclin E is expressed and Cdk2 is activated, that Rb is prevented from binding and inactivating E2F.  (+info)

Regulation of the G1/S transition phase in mesangial cells by E2F1. (77/1403)

It has been established that E2F transcription factors are essential for the regulation of the cell cycle. The E2Fs play an important role in G1/S transition phase, as they regulate the activation of several genes whose products are required for DNA synthesis. E2Fs bind to the retinoblastoma protein family and their transcriptional activities are suppressed in the G0 and early G1 phases. The E2F family consists of a group of five closely related proteins (E2F1 through E2F5). Proliferation of the mesangial cell is a common feature of many glomerular diseases, but the regulation of mesangial cell cycle has not been clarified, nor has the participation of the E2F family in mesangial cells. To elucidate the mechanisms of G1/S transition phase in mesangial cells, we investigated the roles of the E2F family in the mesangial cell cycle. In primary cultured mesangial cells, the protein expression of E2F1 through E2F3 was induced by fetal calf serum (FCS) stimulation. E2F1 especially was strongly induced by mitogenic stimulation. The E2F4 protein was abundantly expressed in the quiescent state and was slightly increased by FCS stimulation. We considered E2F1 to be representative of the E2F family, and used adenovirus-mediated gene transfer to investigate the function of E2F1 to show that overexpression of E2F1 promoted cell cycle progression as measured by a flow cytometer. Furthermore, we investigated the effect of E2F1 overexpression to cyclin D1 and cyclin E expression. Because we previously reported that the regulation of G1 cyclins is a key factor in the G1/S transition phase in mesangial cells, we showed that overexpression of E2F1 induced protein expression of cyclin D1 and cyclin E and increased promoter activity. Thus, we conclude that E2F1 plays an important role in the G1/S transition phase and acts on the mesangial cell cycle through two distinct pathways: (1) E2F1 directly transcribes an S-phase gene, and (2) E2F1 promotes cell cycle progression via the induction of cyclin D1 and cyclin E.  (+info)

Rb and prohibitin target distinct regions of E2F1 for repression and respond to different upstream signals. (78/1403)

E2F transcription factor is subject to stringent regulation by a variety of molecules. We recently observed that prohibitin, a potential tumor suppressor protein, binds to the retinoblastoma (Rb) protein and represses E2F transcriptional activity. Here we demonstrate that prohibitin requires the marked box region of E2F for repression; further, prohibitin can effectively inhibit colony formation induced by overexpression of E2F1 in T47D cells. Prohibitin was also found to interact with the signaling kinase c-Raf-1, and Raf-1 could effectively reverse prohibitin-mediated repression of E2F activity. Agents such as E1A, p38 kinase, and cyclins D and E had no effect on prohibitin-mediated repression of E2F1, but all of these molecules could reverse Rb function. Similarly, stimulation of the immunoglobulin M signaling pathway in Ramos cells could inactivate prohibitin, but this had no effect on Rb function. Serum stimulation of quiescent Ramos cells inactivated Rb and prohibitin with different kinetics; further, while the serum-dependent inactivation of Rb was dependent on cyclin-dependent kinase activity, the inactivation of prohibitin was not. We believe that prohibitin is a novel regulator of E2F function which channels specific signaling cascades to the cell cycle regulatory machinery.  (+info)

The retinoblastoma protein is linked to the activation of Ras. (79/1403)

The inner membrane-bound protein Ras integrates various extracellular signals that are subsequently communicated from the cytoplasm to the nucleus via the Raf/MEK/MAPK cascade. Here we show that the retinoblastoma protein pRb, previously reported to be a nuclear target of this pathway, can in turn influence the activation state of Ras. Rb-deficient fibroblasts display elevated levels (up to 30-fold) of activated Ras during G(1). Expression of wild-type pRb or a number of pRb mutants defective in E2F regulation reverses this effect. We provide evidence that the mid-G(1) activation of Ras in Rb-deficient cells, which occurs at the level of guanine nucleotide binding, differs from that of epidermal growth factor-induced stimulation of Ras, being dependent on protein synthesis. The aberrant levels of Ras activity associated with loss of pRb may be responsible for the differentiation defects in Rb-deficient cells, because suppression of Ras activity in Rb(-/-) fibroblasts restores the transactivation function of MyoD and the expression of a late marker of skeletal muscle differentiation. These data suggest that nuclear-cytoplasmic communication between pRb and Ras is bidirectional.  (+info)

Isolation and initial characterization of the BRCA2 promoter. (80/1403)

The hereditary breast cancer susceptibility gene, BRCA2, is considered to be a tumor suppressor gene that may be involved in the cellular response to DNA damage. The transcript for this gene is cell cycle regulated with mRNA levels reaching a peak just before the onset of DNA synthesis. In order to define the mechanisms by which BRCA2 is transcriptionally regulated, we have begun to study upstream regulatory sequences. In this report, we define a minimal promoter region that has strong activity in human breast epithelial cells. Deletions of this sequence narrowed the strong basal activity to a region extending from -66 to +129 with respect to the BRCA2 transcriptional start site. This sequence demonstrated cell cycle regulated activity with kinetics similar to the endogenous transcript. Examination of the sequence revealed several consensus binding sites for transcription factors including an E-box, E2F and Ets recognition motifs. Electrohoretic mobility shift assays revealed specific protein binding to two sequences upstream of the start site; the palindromic E-box and an Ets/E2F site. Site-directed mutagenesis of either of these sites reduced both the basal activity in log phase cells and the cell cycle regulated activity of the promoter. Mutational inactivation of both sites within the same construct effectively eliminated promoter activity. Antibodies to candidate transcription factors used in super shift experiments revealed specific interactions between the BRCA2 promoter and the basic region/helix - loop - helix containing USF-1 and 2 proteins and Elf-1, an Ets domain protein. Binding of these factors depended upon the presence of intact recognition sequences. The USF factors were shown to bind predominantly as a heterodimeric complex of USF-1 and 2 while Elf-1 bound the promoter when it was not occupied by USF. Co-transfection studies with USF proteins and the varicella zoster IE62 protein provide evidence for the involvement of endogenous and exogenous USF in the activation of the BRCA2 promoter. We propose that interactions between USF-1, USF-2 and Elf-1 play an important role in the transcriptional regulation of the BRCA2 gene.  (+info)