Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

All cellular ets proteins contain a region of high amino acid identity to those found in the last two exons of the ets-1 gene (C domain). We have identified and characterized a new member of the human ETS gene family, ERGB. The ERGB gene shows extensive amino acid identity to the human ERG and the mouse Fli-1 genes. The ERGB gene is found to be transcriptionally active in a variety of human cell lines and tissues, in contrast to the more restrictive expression pattern of the ERG gene. The ERGB gene encodes for a 3.2-kilobase mRNA containing an open reading frame of 451 amino acids. The ERGB gene, like human ETS1, is located on chromosome 11 and is transposed to chromosome 4 as a result of the translocation t(4;11) associated with leukemia. Pulse-field gel analysis suggests that ETS1 and ERGB are more than 200 kilobases apart. Similar to the other members of the ets family (ets 1, ets 2), this new member is also able to trans-activate transcription of a reporter gene linked to the ETS-binding sequences derived from either the GATA-1 promoter or an optimal Ets-binding site.
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PMID:The ERGB/Fli-1 gene: isolation and characterization of a new member of the family of human ETS transcription factors. 144

The t(8;21)(q22;q22) is a nonrandom translocation specifically marking blasts of acute myelogenous leukemia (AML) with undifferentiated phenotype. The breakpoint on chromosome 21 involved by this rearrangement has been precisely localized relative to cloned DNA markers by physical and genetic linkage analysis enabling the use of positional cloning for its isolation. Yeast artificial chromosome (YAC) clones for loci proximal (D21S65) and distal (ERG) to the (21q22) breakpoint have been developed and their chromosome 21 origin and location relative to the breakpoint has been established. By using in situ hybridization analysis, a 240 kb YAC clone for the D21S65 locus clearly identified both derivative chromosomes of the (8;21) translocation in metaphase spreads of leukemia blasts with the rearrangement. The characterization of the DNA sequences contained in this 240 kb YAC can reveal the functional consequences of their derangement in leukemia with abnormalities of the (21q22) region.
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PMID:DNA sequences of chromosome 21-specific YAC detect the t(8;21) breakpoint of acute myelogenous leukemia. 175 77

The human ETS2 gene is a member of the ets gene family (ETS1, ETS2, ERG, ELK1 and ELK2) with amino acid similarity to the v-ets oncogene of the avian leukemia virus, E26. The ETS2 gene is composed of 10 exons, nine of which contribute to the open reading frame encoding 469 amino acids. The ETS2 gene directs the synthesis of three RNA transcripts, which differ from each other by the length of their 3' ends. This heterogeneity of 3' end is the major reason for the size differences between the transcripts, presumably reflecting utilization of three different polyadenylation signals/sites. The coding regions of all of the ETS2 RNA species are the same length and, thus, should contain the same open reading frame.
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PMID:Molecular organization and differential polyadenylation sites of the human ETS2 gene. 225 Sep 10

We describe a patient with an asymmetric double ring 21 in mosaic form, 45,XX, -21/46, XX, -21, +r(21), who has limited manifestations of Down syndrome and who developed acute myelofibrosis and megakaryocytic leukemia (AMKL), FAB M7, a hematologic disorder particularly common in Down syndrome patients. In situ hybridization studies, gene dosage, and DNA polymorphism analysis showed that the ring chromosome carries a duplicated region which extends from D21S406 on the centromeric side and includes marker D21S3 on the telomeric side. FISH studies indicate two sizes of ring 21 in the patient. The origin of the supernumerary chromosome 21 in the proband was paternal; furthermore, the r(21) probably was formed postzygotically. Included in the duplicated segment are the candidate genes for leukemia AML-1, ETS, and ERG. The potential significance of disomic homozygosity of loci on 21q in M7 megakaryocytic leukemia is discussed.
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PMID:Cytogenetic and molecular analysis of a ring (21) in a patient with partial trisomy 21 and megakaryocytic leukemia. 757 23

The t(16;21)(p11;q22) translocation is a recurrent chromosomal abnormality found in several types of myeloid leukemia. We have previously demonstrated that the breakpoints of this translocation are clustered in a specific intron of the ERG gene on chromosome 21, which has recently been reported to be involved in Ewing's sarcoma. We show here that the TLS/FUS gene on chromosome 16 is fused with the ERG gene to produce the TLS/FUS-ERG chimeric transcript by this translocation. The TLS/FUS gene has been identified as a translocated gene in myxoid liposarcoma by the t(12;16)(q13;p11) translocation and encodes an RNA-binding protein that is highly homologous to the product of the EWS gene involved in Ewing's sarcoma. Thus, the TLS/FUS-ERG gene fusion in t(16;21) leukemia is predicted to produce a protein that is very similar to the EWS-ERG chimeric protein responsible for Ewing's sarcoma.
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PMID:An RNA-binding protein gene, TLS/FUS, is fused to ERG in human myeloid leukemia with t(16;21) chromosomal translocation. 818 69

Acute leukemia (AL) is a relatively uncommon, but dreaded, complication occurring with increased frequency in individuals with Down syndrome (DS). This selective update includes aspects of AL in DS in which a change or advancement in our understanding of this disease has occurred. Despite previous reports describing a worse outcome for these individuals, more recent studies have suggested an improved response to current treatment strategies (including high-dose AraC) equaling, or even surpassing, the survival of non-DS individuals with AL. An increased toxicity to methotrexate in DS patients has also been recognized. While the leukemia of DS infants has been described as megakaryoblastic, the spectrum of in vitro differentiation is much broader including (in addition to megakaryocytic colonies) various myeloid, macrophage, and even erythroid colonies. Although the cause(s) of DS-AL remains unknown, potential candidate genes include those encoded on chromosome 21 that play a role in other defined leukemias in non-DS individuals. The AML1/PEBP2alpha gene maps to the DS critical region and is characteristically associated with two leukemia-associated chromosomal translocations: 1) the 8;21 translocation involving an AML1/ETO fusion transcript commonly seen in acute myelogenous leukemia (AML) and; 2) a 3;21 translocation identified in certain chemotherapy-related myelodysplasias/leukemias and occasionally in the blast crisis of chronic myelogenous leukemia cells. Similarly, the ETS-related gene, ERG, involved in the AML 16;21 maps to the q22 region of chromosome 21. Lastly, a familial platelet disorder with a propensity to develop myeloid leukemia has been linked to 21q22.1-22.2 and conceivably might involve AML1, ERG or yet another gene.
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PMID:Down syndrome and leukemia, an update. 854 49

The t(16;21)(p11;q22) translocation is a non-random chromosomal aberration observed in several types of human acute myeloblastic leukemia (AML), whereas the der(16)t(1;16) and chromosome rearrangements at 12q13 are frequently found in solid tumors. A novel cell line YNH-1 was established from peripheral blood cells of a 46-year-old male with AML (M1) carrying t(16;21) and t(1;16) translocations. YNH-1 has been maintained with a doubling time of 82 h for more than 20 months as a granulocyte colony-stimulating factor (G-CSF), granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-3 (IL-3) dependent line. Morphologically YNH-1 cells were free-floating immature myeloblasts with lobulated nuclei and vacuoles in the cytoplasm. They were positive for myeloperoxidase but negative for alpha-naphthyl butylate esterase and chloroacetate esterase stainings. In surface marker analysis YNH-1 cells were positive for CD13, CD33 and CD34. Chromosomal analysis showed 46, XY, der(16)t(16;21)(p11;q22)t(1;16) (q12;q13), der(21)t(16;21)(p11;q22), der (6)t(6;12)(q13;q13), der(12)t(6;12)(q21;q13). These translocations were confirmed by fluorescence in situ hybridization (FISH) studies with the ERG-YAC clone and chromosome-specific DNA libraries. Both the FUS/ERG and ERG/FUS chimeric transcripts were identified by reverse transcriptase-polymerase chain reaction (RT-PCR) analysis. Thus, YNH-1 could be a useful tool for elucidating the pathophysiology and molecular mechanism in AML with t(16;21),t(1;16) and 12q13 translocations.
Leukemia 1997 Apr
PMID:Establishment of a novel human acute myeloblastic leukemia cell line (YNH-1) with t(16;21), t(1;16) and 12q13 translocations. 909 2

The FUS (TLS)-ERG chimeric protein associated with t(16;21)(p11;q22) acute myeloid leukemia is structurally similar to the Ewing's sarcoma chimeric transcription factor EWS-ERG. We found that both FUS-ERG and EWS-ERG could induce anchorage-independent proliferation of the mouse fibroblast cell line NIH 3T3. However, only FUS-ERG was able to inhibit the differentiation into neutrophils of a mouse myeloid precursor cell line L-G and induce its granulocyte colony-stimulating factor-dependent growth. We constructed several deletion mutants of FUS-ERG lacking a part of the N-terminal FUS region. A deletion mutant lacking the region between amino acids 1 and 173 (exons 1 to 5) lost the NIH 3T3-transforming activity but retained the L-G-transforming activity. On the other hand, a mutant lacking the region between amino acids 174 and 265 (exons 6 and 7) lost the L-G-transforming activity but retained the NIH 3T3-transforming activity. These results indicate that the N-terminal region of FUS contains two independent functional domains required for the NIH 3T3 and L-G transformation, which we named TR1 and TR2, respectively. Although EWS intrinsically possessed the TR2 domain, the EWS-ERG construct employed lacked the EWS sequence containing this domain. Since the TR2 domain is always found in chimeric proteins identified from t(16;21) leukemia patients but not in chimeric proteins from Ewing's sarcoma patients, it seems that the TR2 function is required only for the leukemogenic potential. In addition, we identified three cellular genes whose expression was altered by ectopic expression of FUS-ERG and found that these are regulated in either a TR1-dependent or a TR2-dependent manner. These results suggest that FUS-ERG may activate two independent oncogenic pathways during the leukemogenic process by modulating the expression of two different groups of genes simultaneously.
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PMID:Dual transforming activities of the FUS (TLS)-ERG leukemia fusion protein conferred by two N-terminal domains of FUS (TLS). 1052 52

A 29-year-old woman having acute myelogeneous leukemia-M1 subtype with the chromosomal abnormality t(16;21)(p11;q22) is presented. Complete blood count at onset showed a hemoglobin level of 7.2 g/dl, a platelet count of 48 x 10(9)/l, and a white blood cell count of 161.2 x 10(9)/l with 99% blasts and 1% lymphocytes. Bone marrow aspiration revealed massive proliferation of blasts that were positive for CD13, CD33, CD34, CD56 and myeloperoxidase, and negative for other T-cell, B-cell and monocytic markers. After achieving complete remission following conventional chemotherapy, she received an HLA-matched bone marrow transplantation (BMT) from her sibling after conditioning with busulfan, etoposide and cyclophosphamide. However, 9 months later, the leukemia relapsed as a painful extramedullary mass in her left femur. In spite of intensive re-induction chemotherapy, she died of progressive disease and sepsis. Although we could not detect the TLS/FUS-ERG fusion transcripts by reverse transcriptase-polymerase chain reaction in pre-BMT remission phase, they were clearly detectable in bone marrow cells obtained 6 months after transplantation with no translocation detected by conventional cytogenetics. We consider that even high-dose chemotherapy with BMT may not be effective in the eradication of this type of leukemia, and that the detection of minimal residual disease possibly contributes to the better planning of the therapeutic strategy.
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PMID:Detection of minimal residual disease in a patient having acute myelogenous leukemia with t(16;21)(p11;q22) treated by allogeneic bone marrow transplantation. 1134 Feb 53

A 3-year-old boy with poorly prognostic acute megakaryoblastic leukemia (AML M7) showing t(16;21)(p11;q22) karyotype underwent unrelated bone marrow transplantation (U-BMT) during his first hematological remission. The conditioning regimen consisted of BU, VP-16 and L-PAM. Engraftment was smooth, but the patient developed grade I acute GVHD. During hematological remission before U-BMT, the TLS/FUS-ERG chimeric transcript of t(16;21)(p11;q22) was consistently detectable as minimal residual disease (MRD) by RT-PCR. However, after U-BMT it soon became undetectable. There was no detectable MRD until 7 months after U-BMT, but bone marrow relapse occurred 10 months after U-BMT. We consider that U-BMT is a promising treatment for t(16;21)(p11;q22) AML. However, an intensified conditioning regimen or modification of GVHD prophylaxis is needed.
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PMID:[AML(M7) associated with t(16;21)(p11;q22) showing relapse after unrelated bone marrow transplantation and disappearance of TLS/FUS-ERG mRNA]. 1150 30


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