UNIPROT:P51532 - FACTA Search

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Query: UNIPROT:P51532 (transcriptional activator)
6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The IE2 gene product of human cytomegalovirus (HCMV) is one of a few viral regulatory proteins expressed immediately upon infection of the host cell. It is a potent transcriptional activator of many viral and cellular promoters. We found that the retinoblastoma susceptibility gene product (Rb) dramatically suppressed this IE2 transactivation of various promoters. However, unlike another tumor suppressor protein, p53, Rb did not have any significant effect on basal levels of transcription, suggesting that Rb specifically interacts with IE2 rather than other cellular factors involved in the general transcription machinery. We found by protein-affinity chromatography that Rb in nuclear extracts or produced by in vitro translation directly bound to IE2. Our results suggest that Rb may regulate the life cycle of HCMV, which is endemic in the human population. Furthermore, these data may provide new insights into the slow rate of HCMV DNA replication in cells and the possible involvement of HCMV in tumorigenesis.
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PMID:The retinoblastoma gene product negatively regulates transcriptional activation mediated by the human cytomegalovirus IE2 protein. 774 17

The retinoblastoma tumor suppressor protein (RB) binds several cellular proteins involved in cell cycle progression. Using the yeast two-hybrid system, we found that RB bound specifically to the protein BRG1. BRG1 shares extensive sequence similarity to Drosophila brahma, an activator of homeotic gene expression, and the yeast transcriptional activator SNF2/SW12. BRG1 contains an RB-binding motif found in viral oncoproteins and bound to the A/B pocket and the hypophosphorylated form of RB. BRG1 did not bind RB in viral oncoprotein-transformed cells. Coimmunoprecipitation experiments suggested BRG1 associates with the RB family in vivo. In the human carcinoma cell line SW13, BRG1 exhibited tumor suppressor activity by inducing formation of flat, growth-arrested cells. This activity depended on the ability of BRG1 to cooperate and complex with RB, as both an RB-nonbinding mutant of BRG1 and the sequestration of RB by adenovirus E1A protein abolished flat cell formation.
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PMID:The retinoblastoma protein and BRG1 form a complex and cooperate to induce cell cycle arrest. 792 70

E2F is a mammalian transcription factor involved in cell cycle regulation. The retinoblastoma gene product, pRB, binds to E2F in a cell cycle-dependent manner and appears to turn E2F from a transcriptional activator into a repressor. We show here that in vitro binding of pRB has three major effects on the DNA binding properties of E2F affinity-purified from HeLa cells; pRB binding increases the half-life of E2F.DNA complexes 10-15-fold, it reduces E2F specific DNA binding in the presence of nonspecific DNA by sequestering E2F, and it partially reverses the DNA bending induced by E2F. Upon specific DNA binding, E2F induces a DNA bend with a flexure angle of 125 degrees. Both full-length pRB105 and the N-terminally truncated pRB60 bind to the E2F.DNA complex with a Kd,app of 150 pM and reduce the apparent DNA bending to less than 80 degrees. DNA footprinting analysis indicates that the nonspecific DNA binding activity of pRB is not involved in this effect. Our biochemical data suggest that transcriptional activation by E2F may involve DNA bending and that the reversal of bending upon binding of pRB may turn E2F into a repressor.
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PMID:Retinoblastoma protein reverses DNA bending by transcription factor E2F. 812 63

The reversible interaction of the retinoblastoma susceptibility gene product (Rb) with the cellular transcription factor E2F has recently been demonstrated. Activation of the adenovirus E2a promoter by the products of the viral E1a gene correlates with the ability of both early E1a proteins to sequester Rb, thereby releasing E2F from inactive complexes with this protein. The E2a promoter is also efficiently stimulated by a product (17.5 kDa) of the viral E4 gene. The specific interaction of this E4 protein with E2F results in the formation of complexes that bind cooperatively to the two neighboring E2F binding sites in the E2a promoter. We have previously shown that in undifferentiated F9 cells (F9EC) the E2a promoter is refractory to E2F-mediated activation by E1a, but not by E4. Using both band-shift and transfection experiments, we now demonstrate (i) that in F9EC cells the E4 product, in combination with E2F, recruits Rb into a stable multiprotein complex and (ii) that in these undifferentiated cells, as opposed to their differentiated counterpart, Rb is actively involved in the transcriptional stimulation of the E2a promoter by E4. Our results suggest that, depending on the cell state, Rb may behave either as a transcriptional activator (F9EC cells) or as a transcriptional inhibitor (differentiated F9 cells).
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PMID:Rb may act as a transcriptional co-activator in undifferentiated F9 cells. 841

hBRG1 and hBRM are mammalian homologs of the SNF2/SW12 yeast transcriptional activator. These proteins exist in a large multisubunit complex that likely serves to remodel chromatin and, in so doing, facilitates the function of specific transcription factors. The retinoblastoma protein (pRB) inhibits cell cycle progression by repressing transcription of specific growth-related genes. Using the yeast two-hybrid system, we demonstrate that the members of the hBRG1/hBRM family of proteins interact with the pRB family of proteins, which includes pRB, p107, and p130. Interaction between the hBRG1/hBRM family with the pRB family likely influences cellular proliferation, as both hBRG1 and hBRM, but not mutants of these proteins unable to bind to pRB family members, inhibit the formation of drug-resistant colonies when transfected into the SW13 human adenocarcinoma cell line, which lacks endogenous hBRG1 or hBRM. Further, hBRM and two isoforms of hBRG1 induce the formation of flat, growth-arrested cells in a pRB family-dependent manner when introduced into SW13 cells. This flat-cell inducing activity is severely reduced by cotransfection of the wild-type E1A protein and variably reduced by the cotransfection of mutants of E1A that lack the ability to bind to some or all members of the pRB family.
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PMID:Functional interactions between the hBRM/hBRG1 transcriptional activators and the pRB family of proteins. 865 32

Uncontrolled cellular proliferation is the hallmark of human malignant brain tumors. Their growth proceeds inexorably, in part because their cellular constituents have an altered genetic code that enables them to evade the checks and balances of the normal cell cycle. Recently, a number of major advances in molecular biology have led to the identification of several critical genetic and enzymatic pathways that are disturbed in cancer cells resulting in uncontrolled cell cycling. We now know that the progression of a cell through the cell cycle is controlled in part by a series of protein kinases, the activity of which is regulated by a group of proteins called cyclins. Cyclins act in concert with the cyclin-dependent kinases (CDKs) to phosphorylate key substrates that facilitate the passage of the cell through each phase of the cell cycle. A critical target of cyclin-CDK enzymes is the retinoblastoma tumor suppressor protein, and phosphorylation of this protein inhibits its ability to restrain activity of a family of transcription factors (E2F family), which induce expression of genes important for cell proliferation. In addition to the cyclins and CDKS, there is an emerging family of CDK inhibitors, which modulate the activity of cyclins and CDKs. CDK inhibitors inhibit cyclin-CDK complexes and transduce internal or external growth-suppressive signals, which act on the cell cycle machinery. Accordingly, all CDK inhibitors are candidate tumor suppressor genes. It is becoming clear that a common feature of cancer cells is the abrogation of cell cycle checkpoints, either by aberrant expression of positive regulators (for example, cyclins and CDKs) or the loss of negative regulators, including p21Cip1 through loss of function of its transcriptional activator p53, or deletion or mutation of p16ink4A (multiple tumor suppressor 1/CDKN2) and the retinoblastoma tumor suppressor protein. In this review, we describe in detail our current knowledge of the normal cell cycle and how it is disturbed in cancer cells. Because there have now been a number of recent studies showing alterations in cell cycle gene expression in human brain tumors, we will review the derangements in both the positive and negative cell cycle regulators that have been reported for these neoplasms. A thorough understanding of the molecular events of the cell cycle may lead to new opportunities by which astrocytoma cell proliferation can be controlled either pharmacologically or by gene transfer techniques.
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PMID:Current concepts in neuro-oncology: the cell cycle--a review. 914 59

The transcriptional activator E2F1 regulates the expression of genes at the G1/S boundary. We have characterized interactions of the E2F1 activation domain with two general transcription factors, the TATA-box binding protein (TBP) and TFIIH. Two distinct binding sites on E2F1 were identified for TBP (amino acids 386-417 and 415-437) each of which supported activation in mammalian cells when expressed as a fusion to a heterologous DNA-binding domain. Neither of these minimal activation domains independently bound TFIIH; rather, the TFIIH binding site of E2F1 overlaps both domains. Loss of TFIIH-binding by E2F1 resulted in a 60-65% reduction in transactivation, suggesting that the E2F1/TFIIH interaction is important, but not essential, for transactivation. The retinoblastoma protein (Rb) binds directly to E2F1 and represses E2F1-mediated transactivation. We have demonstrated that recombinant Rb can compete with TBP and the p62 subunit of TFIIH for binding to immobilized E2F1. A tumorigenic form of Rb deficient in repressing E2F1-mediated transactivation is likewise deficient in displacing TBP from E2F1. We propose that competition between Rb and both TBP and TFIIH for binding to E2F1 is a mechanism by which Rb inhibits transactivation by E2F1.
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PMID:Modular organization of the E2F1 activation domain and its interaction with general transcription factors TBP and TFIIH. 940 Sep 91

Because most non-melanocytic human skin cancers have p53 mutations, it is unclear whether the aberrant growth of these cancers is simply a result of the abrogation of a p53 downstream mediator, the universal cyclin-dependent kinase inhibitor p21WAF1. To investigate the role of p21WAF1 in human skin carcinogenesis, we studied its regulation in normal and p53-mutated immortalized human keratinocytes. In proliferating human normal keratinocytes (HNK), more wild-type p53 protein (wt p53) was expressed than in growth-arrested differentiating keratinocytes. However, the function of wt p53 as a transcriptional activator of the p21WAF1 gene was suppressed in proliferating keratinocytes. In response to ultraviolet B irradiation, expression of wt p53 increased in proliferating keratinocytes, but p21WAF1 transcriptional activation was not induced. Two isoforms of mdm2 (p57 and p90), which can bind to wt p53 and negatively regulate wt p53 function, were expressed in proliferating HNK, suggesting that mdm2 may play a role in the suppression of wt p53's function in proliferating HNK. Increased expression of p21WAF1 was detected in both Ca(2+)-induced growth-arrested and differentiating HNK, in which the wt p53 expression was down regulated. This reflects the complexity of the p53/p21WAF1 pathways of cell-cycle regulation and differentiation in keratinocytes. No p21WAF1 expression was detected in human immortalized keratinocytes (HaCaT) or in two ras-transformed variants, HaCaT ras I/7 and HaCaT ras II/3, which have two p53 mutations. Retrovirus-mediated expression of p21WAF1 stopped the growth of all these cell types, but expression of wt p53 did not affect the cells' growth properties. p21WAF1 also downregulated human telomerase RNA component mRNA expression in HaCaT cells. This novel function of p21WAF1 partly explains the suppression of telomerase activity by p21WAF1 expression in HaCaT. Taken together, these results are consistent with the idea that p21WAF1 successfully inhibits the growth of non-melanocytic skin cancers, even those with alterations in p53, p21ras, retinoblastoma gene product, and telomerase activity.
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PMID:Growth arrest of immortalized human keratinocytes and suppression of telomerase activity by p21WAF1 gene expression. 947 69

The retinoblastoma protein (Rb) acts as a critical cell-cycle regulator and loss of Rb function is associated with a variety of human cancer types. Here we report that Rb binds to members of the AP-1 family of transcription factors, including c-Jun, and stimulates c-Jun transcriptional activity from an AP-1 consensus sequence. The interaction involves the leucine zipper region of c-Jun and the B pocket of Rb as well as a C-terminal domain. We also present evidence that the complexes are found in terminally differentiating keratinocytes and cells entering the G1 phase of the cell cycle after release from serum starvation. The human papillomavirus type 16 E7 protein, which binds to both c-Jun and Rb, inhibits the ability of Rb to activate c-Jun. The results provide evidence of a role for Rb as a transcriptional activator in early G1 and as a potential modulator of c-Jun expression during keratinocyte differentiation.
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PMID:Rb binds c-Jun and activates transcription. 954 46

We have recently demonstrated that the retinoblastoma family of negative cell cycle regulators can form complexes with a class of developmental factors which contain paired-like (PL) homeodomains (Wiggan et al. [1998] Oncogene 16:227-236). Our screens led to the isolation of a novel PL-homeodomain protein which had been isolated independently by another group and called Alx-4 (Qu et al. [1997] Development 124:3999-4008). Mice homozygous for a targeted null mutation of Alx-4 have several abnormalities, including preaxial polydactyly, suggesting that Alx-4 plays a role in pattern formation in limb buds. In data that we present here, we show that Alx-4 is expressed in mesenchymal condensations of a diverse group of tissues whose development is dependent on epithelial-mesenchymal interactions, many of which are additionally dependent on expression of the HMG-box-containing protein, LEF-1. Alx-4-expressing tissues include osteoblast precursors of most bones, the dermal papilla of hair and whisker follicles, the dental papilla of teeth, and a subset of mesenchymal cells in pubescent mammary glands. We show further that Alx-4 strongly activates transcription from a promoter containing the homeodomain binding site, P2. Optimal activation requires specific sequences in the N-terminal portion of Alx-4 as well as a proline-rich region downstream of the PL-homeodomain, but not the paired-tail at the C terminus. Taken together, our results demonstrate that Alx-4 is a potent transcriptional activator that is expressed at sites of epithelial-mesenchymal interactions during murine embryonic development.
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PMID:Alx-4, a transcriptional activator whose expression is restricted to sites of epithelial-mesenchymal interactions. 978 16

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