Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P51532 (transcriptional activator)
 6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The ets gene superfamily encodes a class of transcription factors that bind to a purine rich sequence through a 85 amino-acid ETS domain. Among them, the human erg gene has been found to be involved in Ewing's sarcoma, primitive neurectodermal tumour of childhood and acute myeloid leukaemia. Nevertheless, little is known about human erg expression. Northern blot analyses have shown a human erg expression restricted to few cell lines and thymus, but the status concerning expression during development remains unknown probably because no homologue of this gene has yet been isolated and studied in other vertebrates. We thus choose to clone the chicken erg gene (ck-erg) and to study its expression during chicken development. We obtained a bona fide clone of ck-erg and defined the transcriptional modulating properties of its product. The ck-Erg protein acts as a transcriptional activator through a conventional consensus ETS binding site. Northern blot studies on various chicken tissues, in situ analyses and comparison with the well-characterised c-ets-1 expression show that ck-erg is expressed in mesoderm- and, to a lesser extent, in ectoderm-derived tissues. During chicken development, two salient features could be observed. From stage E1 to E3.5, ck-erg expression was widely distributed in mesodermal derivatives and neural crest, resembling c-ets-1 expression. However, by E6, the expression of ck-erg exhibited, unlike c-ets-1, a drastically new and strong signal in precartilaginous condensation zones and cartilaginous skeletal primordia. These stages are the first steps of bone formation during skeletal elaboration. Our results show for the first time a possible specific involvement of ck-erg in cartilage morphogenesis.
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PMID:Mesodermal expression of the chicken erg gene associated with precartilaginous condensation and cartilage differentiation. 760 48

EWS and TLS/FUS genes, which code for RNA binding proteins are involved in a wide variety of human solid tumors. The TLS/FUS gene is involved both in human myxoid liposarcomas which carry a characteristic chromosomal translocation, t(12;16)(q13;p11) and in human myeloid leukemias with recurrent chromosomal translocation, t(16;21)(p11:q22). The TLS/FUS gene is fused to a transcriptional repressor, CHOP (in human myxoid liposarcomas) or transcriptional activator, erg (in human myeloid leukemias). To understand better the functional role of TLS/FUS-erg in human myeloid leukemias, we have cloned the TLS/FUS and TLS/FUS-erg cDNAs and studied the functional properties of their gene products. TLS/FUS protein binds to RNA in vitro and shows preferential binding to poly G. Both the amino- and the carboxy- terminal regions of TLS/FUS containing the conserved RNA binding motifs are needed for poly G specific RNA binding activity. The TLS/FUS fusion domain (TFD) appears to regulate the DNA binding activity of TLS/FUS-erg chimeric protein which shows weaker transcriptional activation properties compared to normal erg proteins. Mutational analysis of the TLS/FUS-erg chimeric protein reveals TFD to function as a transcriptional activation domain thus replacing the amino terminal transcriptional activation domain of the erg protein. Therefore alterations in both DNA binding and transcriptional activation properties of aberrant erg proteins may be responsible for the genesis of t(16;21) chromosomal translocation-bearing human myeloid leukemias.
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PMID:TLS/FUS fusion domain of TLS/FUS-erg chimeric protein resulting from the t(16;21) chromosomal translocation in human myeloid leukemia functions as a transcriptional activation domain. 797 Jul 32

The EWS gene, which maps to band q12 of human chromosome 22, is involved in a wide variety of human solid tumors including Ewing sarcoma, related primitive neuroectodermal tumors, malignant melanoma of soft parts and desmoplastic small round cell tumors. In these tumors, the EWS is fused to genes encoding transcriptional activators/repressors, like Fli-1 or erg or ATF 1 or wt1. To better understand the function of the EWS protein, we cloned the EWS cDNA. Sequence analysis of this cDNA revealed differential splicing involving two exons encoding 72 amino acids. Both alternatively spliced transcripts, EWS and EWS-b, are expressed in a variety of cells. Because EWS proteins contain putative conserved RNA binding motifs, we studied the RNA binding properties of the EWS protein. The EWS-b protein binds to RNA in vitro and, specifically, to poly G and poly U. The RNA binding activity was localized to the carboxy terminal 86 amino acids, which constitute RGG box. Thus the amino terminal domain of EWS (NTD-EWS), which is involved in chromosome translocation may regulate the specificity of RNA binding activity of EWS. An EWS-erg chimeric protein, which is found in Ewing's sarcoma cells, functions as a transcriptional activator. Mutational analysis of EWS-erg chimeric protein revealed that NTD-EWS functions as a regulatory domain for the transcriptional activation properties of EWS-erg chimeric protein.
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PMID:The EWS gene, involved in Ewing family of tumors, malignant melanoma of soft parts and desmoplastic small round cell tumors, codes for an RNA binding protein with novel regulatory domains. 808 18

ets oncogene superfamily consists of a family of transcriptional factors that functions as activators and/or repressors. Previously, we have identified a member of this ets superfamily namely erg, ets related gene. erg gene was shown to code for at least two proteins erg-1 and erg-2 because of alternative splicing and alternative usage of initiation codon. In this report we show that erg gene codes for an additional erg variant protein, erg-3 as a result of differential splicing which results in the insertion of 24 amino acids in the coding region of erg-2 protein. RNAase protection analysis revealed that erg-3 transcripts are expressed in a variety of cells. Erg-3 was also found to activate the transcription of the reporter TK-CAT gene linked to erg target sequences suggesting that erg-3 codes for a sequence specific transcriptional activator.
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PMID:Differentially spliced erg-3 product functions as a transcriptional activator. 829 Feb 79

Three of the ets oncogene superfamily members v-ets, Spi-1/PU.1 and Fli-1, have been shown to be directly involved in retroviral-mediated acute erythroleukemias. The Fli-1 gene was found to be rearranged in 75% of the erythroleukemias induced by Friend murine leukemia virus (F-MuLV), suggesting that it could play a key role in cellular transformation. We have previously isolated and characterized the human Fli-1 gene and have found it to be highly homologous (80%) to the human erg-2 gene. Human Fli-1 was also shown to be rearranged in Ewing's sarcoma cases, in which the amino-terminal region of the Fli-1 gene was replaced with a novel coding region of a putative RNA-binding protein, EWS. In this report, we show that the recombinant Fli-1 protein expressed in bacteria binds to DNA in a sequence-specific manner. It appears that Fli-1 and erg proteins fall into the category of ets proteins that recognize limited ets target sequences, unlike c-ets-1, ets-2 and Elk-1. The Fli-1 gene was found to activate the transcription of the reporter gene that was linked to Fli-1 target sequences, suggesting that Fli-1 is a sequence-specific transcriptional activator. Deletion analysis revealed the presence of two autonomous transcriptional activation domains, one at the amino-terminal region (amino-terminal transcriptional activation domain, ATA) and the other at the carboxy-terminal region (carboxy-terminal transcriptional activation domain, CTA). Secondary structural analysis of ATA and CTA domains revealed the presence of helix-loop-helix (H-L-H) and/or turn-loop-turn (T-L-T) regions. From these results it appears that a portion of the Fli-1 ATA domain (H-L-H region) was replaced by the amino-terminal domain of EWS gene in Ewing's sarcoma cases. Therefore alteration in the transcriptional activation function of Fli-1 may be responsible for human malignancies such as sarcomas, leukemias and lymphomas in which this gene is rearranged.
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PMID:Analysis of the DNA-binding and transcriptional activation functions of human Fli-1 protein. 833 42

erg, an ets related gene encodes a sequence specific DNA binding transcriptional activator protein. We have identified four functional domains of erg protein that are responsible for DNA binding, transcriptional activation and negative regulation of transcriptional activation. Deletion analysis revealed that the 3'-ets domain of the erg protein is sufficient for DNA binding activity. Analysis of these deletion mutants also revealed the presence of two autonomous transcriptional activation domains, one at the amino and the other at the carboxyterminal region. This aminoterminal transcriptional activator domain (5'-ets domain) is conserved in six of the ets genes suggesting that it (ETA, ets Transcriptional Activation domain) may contribute to a common function among these genes. The transcriptional activation function of the carboxy terminal transcriptional activation domain (CTA) was inhibited by the presence of a Negative Regulatory Transcriptional activation domain (NRT), which is located at the amino terminal region of erg DNA binding domain. These results may help in understanding the structure/function relationship of other erg/ets related proteins.
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PMID:Characterization of the DNA binding and transcriptional activation domains of the erg protein. 851 Sep 21

Two ets family members, namely erg and Fli-1 are fused with two EWS family members namely EWS and TLS/FUS as a result of chromosome translocation in human solid tumors and leukemias. EWS-erg and EWS-Fli-1, which are involved in greater than 95% of Ewing family of tumors, were shown to function as transcriptional activators. TLS/FUS-erg, which is involved in human myeloid leukemias also functions as a transcriptional activator. Expression of these fusion proteins (EWS-erg and EWS-Fli-1) are shown to be essential for maintaining the oncogenic and tumorigenic properties of tumor cells. Cancer is thought to be caused not only by uncontrolled cell proliferation but also by deregulation of programmed cell death. Therefore, we have studied the role of normal (Fli-1 and erg) and aberrant fusion proteins (EWS-erg, EWS-Fli-1 and TLS/FUS-erg) in apoptosis. We have found that expression of normal (Fli-1 and erg) and aberrant fusion proteins inhibit the apoptosis of NIH3T3 cells induced by either serum deprivation or by treatment with calcium ionophore. We have also observed similar suppression of apoptosis in Ewing's sarcoma cells expressing EWS-Fli-1 and EWS-erg proteins suggesting that these fusion proteins may be responsible for the decreased ability of these tumor cells to undergo apoptosis. Inhibition of the expression of these aberrant fusion proteins by antisense RNA technique resulted in increased susceptibility to apoptosis leading to the death of tumor cells. Therefore, our results suggest that one can use therapeutic agents which can down regulate the expression of fusion proteins in combination with chemotherapeutic agents as an effective treatment for these human solid tumors and leukemias.
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PMID:Inhibition of apoptosis by normal and aberrant Fli-1 and erg proteins involved in human solid tumors and leukemias. 917 86