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Enzyme
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Query: UNIPROT:P51532 (
transcriptional activator
)
6,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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.
...
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
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.
...
PMID:Inhibition of apoptosis by normal and aberrant Fli-1 and erg proteins involved in human solid tumors and leukemias. 917 86
As a result of the t(11;22)(q24;q12) chromosomal translocation characterizing the Ewing family of tumors (ET), the amino terminal portion of EWS, an RNA binding protein of unknown function, is fused to the DNA-binding domain of the ets transcription factor Fli1. The hybrid EWS-Fli1 protein acts as a strong
transcriptional activator
and, in contrast to wildtype Fli1, is a potent transforming agent. Similar rearrangements involving EWS or the highly homologous
TLS
with various transcription factors have been found in several types of human tumors. Employing yeast two-hybrid cloning we isolated the seventh largest subunit of human RNA polymerase II (hsRPB7) as a protein that specifically interacts with the amino terminus of EWS. This association was confirmed by in vitro immunocoprecipitation. In nuclear extracts, hsRPB7 was found to copurify with EWS-Fli1 but not with Fli1. Overexpression of recombinant hsRPB7 specifically increased gene activation by EWS-chimeric transcription factors. Replacement of the EWS portion by hsRPB7 in the oncogenic fusion protein restored the transactivating potential of the chimera. Our results suggest that the interaction of the amino terminus of EWS with hsRPB7 contributes to the transactivation function of EWS-Fli1 and, since hsRPB7 has characteristics of a regulatory subunit of RNA polymerase II, may influence promoter selectivity.
...
PMID:Oncogenic EWS-Fli1 interacts with hsRPB7, a subunit of human RNA polymerase II. 970 26
TLS
/FUS is a nucleic acid-binding protein whose N-terminal half functions as a
transcriptional activator
domain in fusion oncoproteins found in human leukemias and liposarcomas. Previous reports have suggested a role for
TLS
/FUS in transcription and splicing processes. Here we report the association of
TLS
/FUS with the nuclear matrix and investigate its role in splicing. Splicing of two pre-mRNAs was inhibited in a
TLS
/FUS-immunodepleted extract and could only be partly restored by addition of recombinant
TLS
/FUS or/and SR proteins, known interaction partners of
TLS
/FUS. The subsequent analysis of
TLS
/FUS immunoprecipitates revealed that, in addition to the SR proteins SC35 and SRp75, the splicing factor PTB (hnRNPI) and the splicing coactivator SRm160 are complexed with
TLS
/FUS, thus explaining the inability to restore splicing completely. Coimmunolocalization confirmed the nuclear matrix association and interaction of
TLS
/FUS with PTB, SR proteins, and SRm160. Our results suggest that the matrix protein
TLS
/FUS plays a role in spliceosome assembly.
...
PMID:Proto-oncoprotein TLS/FUS is associated to the nuclear matrix and complexed with splicing factors PTB, SRm160, and SR proteins. 1258 38
The proto-oncoprotein SYT is involved in the unique translocation t(X;18) found in synovial sarcoma SYT-SSX fusions. SYT has a conserved N-terminal domain (SNH domain) that interacts with the human paralog of Drosophila Brahma (hBRM) and Brahma-related gene 1 (BRG1) chromatin remodeling proteins and a C-terminal transactivating sequence rich in glutamine, proline, glycine, and tyrosine (QPGY domain). Here we reported the isolation of the ribonucleoprotein SYT-interacting protein/co-activator activator (SIP/CoAA), which specifically binds the QPGY domain of SYT and also the SYT-SSX2 translocation fusion. SIP/CoAA is a general nuclear co-activator and an RNA splicing modulator that contains two RNA recognition motifs and multiple hexapeptide repeats. We showed that the region consisting of the hexapeptide motif (YQ domain) is similar to the hexapeptide repeat domain found in EWS and in
TLS
/FUS family proteins. The YQ domain also resembles the QPGY region of SYT itself and like all these other domains acts as a
transcriptional activator
in reporter assays. Most interestingly, the last 84 amino acids adjacent to YQ down-modulate by 25-fold the YQ transactivation of the reporter gene, and both domains are important for SIP/CoAA binding to SYT. In addition, SYT acts together with SIP/CoAA in stimulating estrogen and glucocorticoid receptor-dependent transcriptional activation. Activation is hormone-dependent and requires functional hBRM and/or BRG1. The stimulation is strongly reduced if the N-terminal region of hBRM/BRG1 (amino acids 1-211) is deleted. This region encompasses the SNF11 binding domain (amino acids 156-211), which interacts specifically with SYT in vivo and in vitro.
...
PMID:The proto-oncoprotein SYT interacts with SYT-interacting protein/co-activator activator (SIP/CoAA), a human nuclear receptor co-activator with similarity to EWS and TLS/FUS family of proteins. 1622 27
Many macrophage-specific promoters lack classical transcriptional start site elements such as TATA boxes and Sp1 sites. One example is the CSF-1 receptor (CSF-1R, CD115, c-fms), which is used as a model of the transcriptional regulation of macrophage genes. To understand the molecular basis of start site recognition in this gene, we identified cellular proteins binding specifically to the transcriptional start site (TSS) region. The mouse and human csf1r TSS were identified using cap analysis gene expression (CAGE) data. Conserved elements flanking the TSS cluster were analyzed using EMSAs to identify discrete DNA-binding factors in primary bone marrow macrophages as candidate transcriptional regulators. Two complexes were identified that bind in a highly sequence-specific manner to the mouse and human TSS proximal region and also to high-affinity sites recognized by myeloid zinc finger protein 1 (Mzf1). The murine proteins were purified by DNA affinity isolation from the RAW264.7 macrophage cell line and identified by mass spectrometry as EWS and FUS/
TLS
, closely related DNA and RNA-binding proteins. Chromatin immunoprecipitation experiments in bone marrow macrophages confirmed that EWS, but not FUS/
TLS
, was present in vivo on the CSF-1R proximal promoter in unstimulated primary macrophages. Transfection assays suggest that EWS does not act as a conventional
transcriptional activator
or repressor. We hypothesize that EWS contributes to start site recognition in TATA-less mammalian promoters.
...
PMID:The Ewing sarcoma protein (EWS) binds directly to the proximal elements of the macrophage-specific promoter of the CSF-1 receptor (csf1r) gene. 1845 93
Replication-dependent histone genes are up-regulated during the G1/S phase transition to meet the requirement for histones to package the newly synthesized DNA. In mammalian cells, this increment is achieved by enhanced transcription and 3' end processing. The non-polyadenylated histone mRNA 3' ends are generated by a unique mechanism involving the U7 small ribonucleoprotein (U7 snRNP). By using affinity purification methods to enrich U7 snRNA, we identified FUS/
TLS
as a novel U7 snRNP interacting protein. Both U7 snRNA and histone transcripts can be precipitated by FUS antibodies predominantly in the S phase of the cell cycle. Moreover, FUS depletion leads to decreased levels of correctly processed histone mRNAs and increased levels of extended transcripts. Interestingly, FUS antibodies also co-immunoprecipitate histone
transcriptional activator
NPAT and transcriptional repressor hnRNP UL1 in different phases of the cell cycle. We further show that FUS binds to histone genes in S phase, promotes the recruitment of RNA polymerase II and is important for the activity of histone gene promoters. Thus, FUS may serve as a linking factor that positively regulates histone gene transcription and 3' end processing by interacting with the U7 snRNP and other factors involved in replication-dependent histone gene expression.
...
PMID:FUS/TLS contributes to replication-dependent histone gene expression by interaction with U7 snRNPs and histone-specific transcription factors. 2625 Jan 15
The t(16;21)(p11;q22) is a rare chromosomal abnormality that appears in approximately 1% of acute myeloid leukemia (AML) cases. Previously, between 50 and 60 cases have been reported. In this review, we will discuss the literature regarding t(16;21) as well as cases published. We compiled 68 cases from the Mitelman Database of Chromosome Aberrations and Gene Fusions in Cancer as well as 10 additional cases in the literature, for a total of 78 cases. The t(16;21) results in the
TLS
(FUS)-ERG fusion protein, which is believed to function as a
transcriptional activator
in leukemogenesis and has been demonstrated to interfere in normal pre-mRNA splicing functions of FUS/
TLS
. Reverse-transcriptase polymerase chain reaction of fusion transcripts in patients, has been demonstrated to have diagnostic significance in monitoring for minimal residual disease. Cytogenetically, about half of the cases had secondary chromosomal abnormalities; we found that trisomy 8 and 10 were the most common abnormalities, occurring in 9.1% of the otal cases for each. t(16;21) in AML has been described with various morphological features, such as phagocytosis and vacuolation, and is present in multiple FAB types. Immunophenotypic characteristics such as CD33 and CD34 expression have also been noted, and several studies have examined the relation between CD56 receptor expression and t(16;21) AML. In general, t(16;21) in AML is associated with a poor prognosis and this abnormality could serve as cytogenetic indicator in determining diagnosis and prognosis. Herein, we summarize the cytogenetic features found in the the Mitelman Database of Chromosome Aberrations and Gene Fusions in Cancer for t(16;21) in AML, as well as review the current literature associated with t(16;21), AML and its features.
...
PMID:A t(16;21)(p11;q22) in Acute Myeloid Leukemia (AML) Resulting in Fusion of the FUS/TLS and ERG Genes: A Review of the Literature. 2718 48
