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Symptom
Drug
Enzyme
Compound
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Query: UMLS:C0023467 (
acute myeloid leukemia
)
35,200
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The t(6;9) that characterizes a specific subtype of
ANLL
fuses the 3' part of a gene located on chromosome 9q34, CAN, to the 5' part of a gene located on chromosome 6p23, DEK. On the 6p- chromosome, the resulting DEK-CAN fusion gene is transcribed into a leukaemia-specific 5.5 kb chimaeric mRNA that encodes a putative DEK-CAN fusion protein. No transcription could be detected from the reciprocal CAN-DEK fusion on chromosome 9q+. Analysis of 17 t(6;9)
ANLL
cases showed that the translocation breakpoints occur in a single intron of 7.5 kb in the CAN gene (ICB9) and in a single intron of 9 kb in the DEK gene (ICB6). As a result, the presence of a t(6;9) in blood or bone marrow cells can be faithfully diagnosed by Southern blotting. Moreover, the result of the translocation is an invariable DEK-CAN transcript, which can be sensitively monitored by RNA-PCR. Surprisingly, a
SET
-CAN fusion gene was found in leukaemic cells from a patient with AUL. Like CAN,
SET
is located on chromosome 9q34, which explains the apparently normal karyotype of the leukaemic cells. The occurrence of a
SET
-CAN fusion gene indicates that CAN may be the relevant oncogene involved in leukaemogenesis, and that activation of CAN can be effectuated through fusion of its 3' part to either DEK or
SET
. As yet, the function of CAN, DEK or
SET
is unknown. None of the proteins shows consistent homology to any known protein sequences. However, preliminary localization data and analysis of sequence motifs suggested that DEK-CAN may have a role in transcription regulation. CAN contains several dimerization domains and a repeated motif that can function as an ancillary DNA-binding domain. DEK and
SET
are non-related proteins, but they share a stretch of acidic amino acids, which is also present in the fusion proteins.
...
PMID:Translocation t(6;9) in acute non-lymphocytic leukaemia results in the formation of a DEK-CAN fusion gene. 130 67
The t(6;9) associated with a subtype of
acute myeloid leukemia
(
AML
) was shown to generate a fusion between the 3' part of the CAN gene on chromosome 9 and the 5' part of the DEK gene on chromosome 6. The same part of the CAN gene appeared to be involved in a case of acute undifferentiated leukemia (AUL) as well, where it was fused to the SET gene. Genomic sequences around the translocation breakpoint were determined in two t(6;9) samples and in the case of the
SET
-CAN fusion. Although coexpression of myeloid markers and terminal deoxynucleotidyl transferase was shown to be one of the characteristics of t(6;9)
AML
, no addition of random nucleotides at the translocation breakpoint could be found. In addition, the breakpoint regions did not reveal heptamer-nonamer sequences, purine-pyrimidine tracts, a chi-octamer motif, or Alu repeats. The sequence in which the translocation breakpoints occurred was enriched in A/T. Notably, the specific introns in which clustering of breakpoints occurs in DEK and CAN both contain a LINE-I element. As LINE-I elements occur with a moderate frequency in the human genome, the presence of such an element in both breakpoint regions may be more than coincidental and may play a role in the translocation process.
...
PMID:Characterization of the translocation breakpoint sequences of two DEK-CAN fusion genes present in t(6;9) acute myeloid leukemia and a SET-CAN fusion gene found in a case of acute undifferentiated leukemia. 138 75
The translocation (6;9)(p23;q34) in
acute nonlymphocytic leukemia
results in the formation of a highly consistent dek-can fusion gene. Translocation breakpoints invariably occur in single introns of dek and can, which were named icb-6 and icb-9, respectively. In a case of acute undifferentiated leukemia, a breakpoint was detected in icb-9 of can, whereas no breakpoint could be detected in dek. Genomic and cDNA cloning showed that instead of dek, a different gene was fused to can, which was named set. set encodes transcripts of 2.0 and 2.7 kb that result from the use of alternative polyadenylation sites. Both transcripts contain the open reading frame for a putative
SET
protein with a predicted molecular mass of 32 kDa. The set-can fusion gene is transcribed into a 5-kb transcript that contains a single open reading frame predicting a 155-kDa chimeric
SET
-CAN protein. The
SET
sequence shows homology with the yeast nucleosome assembly protein NAP-I. The only common sequence motif of
SET
and DEK proteins is an acidic region.
SET
has a long acidic tail, of which a large part is present in the predicted
SET
-CAN fusion protein. The set gene is located on chromosome 9q34, centromeric of c-abl. Since a dek-can fusion gene is present in t(6;9)
acute myeloid leukemia
and a set-can fusion gene was found in a case of acute undifferentiated leukemia, we assume that can may function as an oncogene activated by fusion of its 3' part to dek, set, or perhaps other genes.
...
PMID:Can, a putative oncogene associated with myeloid leukemogenesis, may be activated by fusion of its 3' half to different genes: characterization of the set gene. 163 Apr 50
Fusion genes encoding the 3' part of the can gene are implicated in two types of leukemia. The dek-can fusion gene is present in t(6;9)
acute myeloid leukemia
and the set-can fusion gene is present in one case of acute undifferentiated leukemia. In order to obtain leads towards the molecular basis of these diseases, we have studied the cellular localization of the DEK-CAN and
SET
-CAN fusion proteins and their normal counterparts. DEK-CAN and
SET
-CAN were localized exclusively in the nucleus, and also DEK and
SET
were found to be nuclear proteins. However, CAN was mainly located at the nuclear and cytoplasmic face of the nuclear envelope. This observation is in accordance with the presence of an amino acid repeat in the C-terminal part of CAN, common to the family of nucleoporins. The C-terminal part also contains a nuclear location domain as shown by deletion analysis. This domain may be important for the presence of CAN at the nucleoplasmic side of the nuclear envelope. The relocation of the carboxyterminal part of CAN due to DEK-CAN and
SET
-CAN may reinforce a nuclear function of the CAN protein.
...
PMID:Relocation of the carboxyterminal part of CAN from the nuclear envelope to the nucleus as a result of leukemia-specific chromosome rearrangements. 775 51
The translocation (6;9) in
acute nonlymphocytic leukemia
results in the formation of a dek-can fusion gene. In a case of acute undifferentiated leukemia, the oncogene can is fused to a different gene, named set, instead of dek and is assumed to be activated. Transcripts of set encode a putative
SET
protein with a predicted molecular mass of 32 kDa. We identified
SET
as a 39-kDa protein by immunoprecipitation with rabbit antiserum against each of three synthetic peptides predicted from the open reading frame of the set gene. We confirmed this identification of
SET
by protein sequencing. We also observed that
SET
is expressed ubiquitously in various human cell lines.
SET
is phosphorylated on serine residue(s) in cultured cells and is localized predominantly in nuclei. Although the function(s) of
SET
and
SET
-CAN is not known, we propose that
SET
plays a key role in the mechanism of leukemogenesis in acute undifferentiated leukemia, perhaps by activating CAN in nuclei and stimulating the transformation potential of
SET
-CAN. This proposed role would therefore be similar to the roles observed for BCR and DEK of the chimeric oncoproteins BCR-ABL and DEK-CAN in
acute myeloid leukemia
and
acute nonlymphocytic leukemia
, respectively.
...
PMID:Identification and characterization of SET, a nuclear phosphoprotein encoded by the translocation break point in acute undifferentiated leukemia. 829 83
The recurrent chromosomal translocation (6;9) is associated with
acute myeloid leukemia
and results in expression of the DEK-CAN fusion protein. This oncoprotein consists of almost the entire DEK protein fused to the C-terminal two-thirds of the CAN protein. In much the same way, CAN is fused to
SET
in a patient with acute undifferentiated leukemia, producing a
SET
-CAN fusion protein. Interestingly, CAN is associated with the nuclear pore complex (NPC) and we recently established its crucial role in nucleocytoplasmic transport processes and cell cycle progression. As a first step in the biochemical analysis of the oncogenic mechanism associated with translocation (6;9), we set out to identify proteins that interact with CAN and its fusion proteins. We found that two proteins specifically co-immunoprecipitate with CAN. One had a molecular mass of 88 kDa protein (CC88) and was determined to associate with the central region of CAN that contains several protein interaction motifs. A second protein of 112 kDa (CC112) was found to interact with the C-terminal nucleoporin-specific repeat of CAN, a region that is supposed to function in nucleocytoplasmic transport. CC112 also interacts with the DEK-CAN and
SET
-CAN fusion proteins. This finding suggests that CC112 may contribute an essential function to the leukemogenic effect of DEK-CAN and
SET
-CAN.
...
PMID:Interaction of cellular proteins with the leukemia specific fusion proteins DEK-CAN and SET-CAN and their normal counterpart, the nucleoporin CAN. 889 27
Presenilin plays critical roles in the genesis of Alzheimer's disease and in LIN-12/Notch signaling during development. Here, we describe a screen for genes that influence presenilin level or activity in Caenorhabditis elegans. We identified four spr (suppressor of presenilin) genes by reverting the egg-laying defective phenotype caused by a null allele of the sel-12 presenilin gene. We analyzed the spr-2 gene in some detail. We show that loss of spr-2 activity suppresses the egg-laying defective phenotype of different sel-12 alleles and requires activity of the hop-1 presenilin gene, suggesting that suppression is accomplished by elevating presenilin activity rather than by bypassing the need for presenilin activity. We also show that SPR-2 is a nuclear protein and is a member of a protein subfamily that includes human
SET
, which has been identified in numerous different biochemical assays and at translocation breakpoints associated with a subtype of
acute myeloid leukemia
.
...
PMID:spr-2, a suppressor of the egg-laying defect caused by loss of sel-12 presenilin in Caenorhabditis elegans, is a member of the SET protein subfamily. 1111 62
Haploinsufficiency of the NSD1 gene is a hallmark of Sotos syndrome, and rearrangements of this gene by translocation can cause
acute myeloid leukemia
. The NSD1 gene product is a
SET
-domain histone lysine methyltransferase that has previously been shown to interact with nuclear receptors. We describe here a novel NSD1-interacting protein, Nizp1, that contains a SCAN box, a KRAB-A domain, and four consensus C2H2-type zinc fingers preceded by a unique finger derivative, referred to herein as the C2HR motif. The C2HR motif functions to mediate protein-protein interaction with the cysteine-rich (C5HCH) domain of NSD1 in a Zn(II)-dependent fashion, and when tethered to RNA polymerase II promoters, represses transcription in an NSD1-dependent manner. Mutations of the cysteine or histidine residues in the C2HR motif abolish the interaction of Nizp1 with NSD1 and compromise the ability of Nizp1 to repress transcription. Interestingly, converting the C2HR motif into a canonical C2H2 zinc finger has a similar effect. Thus, Nizp1 contains a novel type of zinc finger motif that functions as a docking site for NSD1 and is more than just a degenerate evolutionary remnant of a C2H2 motif.
...
PMID:Nizp1, a novel multitype zinc finger protein that interacts with the NSD1 histone lysine methyltransferase through a unique C2HR motif. 1516 84
A mutation in the JH2 pseudokinase domain of the Janus kinase 2 gene (JAK2 V617F) has been described in chronic myeloproliferative disorders (MPD). We screened 79
acute myeloid leukemia
(
AML
) cell lines and found five positive for JAK2 V617F (HEL, MB-02, MUTZ-8,
SET
-2, UKE-1), 4/5 with histories of MPD/MDS. While
SET
-2 expressed both mutant (mu) and wild-type (wt) JAK2, remaining positives carried homo-/hemizygous JAK2 mutations. Microsatellite analysis confirmed losses of heterozygosity (LOH) affecting the JAK2 region on chromosome 9p in MB-02, MUTZ-8 and UKE-1, but also in HEL, the only JAK2mu cell line lacking any reported MPD/MDS history. All five JAK2mu cell lines displayed cytogenetic hallmarks of MDS, namely losses of 5q or 7q, remarkably in 4/5 cases affecting both chromosomes. Our combined FISH and microsatellite analysis uncovered a novel mechanism to supplement mitotic recombination previously proposed to explain JAK2 LOH, namely chromosome deletion with/without selective JAK2mu amplification. Confirming the importance of the mutated JAK2 protein for growth and prevention of apoptosis, JAK2mu cell lines displayed higher sensitivities to JAK2 inhibition than JAK2wt cell lines. In summary, JAK2 V617F cell lines, derived from patients with history of MPD/MDS, represent novel research tools for elucidating the pathobiology of this JAK2 mutation.
...
PMID:JAK2 V617F tyrosine kinase mutation in cell lines derived from myeloproliferative disorders. 1640 98
Leukemia-specific chromosome translocations involving the nucleoporin CAN/NUP214 lead to expression of different fusion genes including DEK-CAN, CAN-ABL, and
SET
-CAN. DEK-CAN and CAN-ABL1 are associated with
acute myeloid leukemia
and T-cell acute lymphoblastic leukemia, respectively, whereas
SET
-CAN was identified in a patient with acute undifferentiated leukemia. In addition,
SET
is overexpressed in solid tumors of the breast, uterus, stomach, and rectum. Ectopic expression of
SET
-CAN inhibits vitamin-D(3)-induced differentiation of the human promonocytic U937cells, whereas ectopic
SET
expression induces differentiation. Here, we assessed the leukemogenic potential of
SET
-CAN in the hematopoietic system of transgenic mice. Although
SET
-CAN mice showed expansion of an early progenitor cell pool and partial depletion of lymphocytes, the animals were not leukemia-prone and did not show shortening of disease latency after retroviral tagging. This suggests that
SET
-CAN expression in acute undifferentiated leukemia might determine the primitive phenotype of the disease, whereas secondary genetic lesions are necessary for disease development. Surprisingly,
SET
-CAN mice developed spontaneous hyperplasia of the stomach mucosa, which coincided with overexpression of beta-catenin and vastly increased numbers of proliferating gastric mucosa cells, suggesting a role of
SET
-CAN in proliferation of certain epithelial cells.
...
PMID:SET-CAN, the product of the t(9;9) in acute undifferentiated leukemia, causes expansion of early hematopoietic progenitors and hyperproliferation of stomach mucosa in transgenic mice. 1756 77
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