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Query: UMLS:C0026986 (
myelodysplastic syndrome
)
14,926
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Double minute chromosomes (dmin) are small chromatin bodies consisting of genes amplified in an extrachromosomal location. dmins are uncommon in hematologic malignancies; they are seen primarily in acute myeloid leukemia, with amplification of the MYC oncogene or, less frequently, the MLL transcription factor. Nine patients with hematologic malignancies with dmin were seen at the Roswell Park Cancer Institute between 1985 and 2000; eight had acute myeloid leukemia and one a
myelodysplastic syndrome
. Fluorescence in situ hybridization (FISH) demonstrated MYC amplification on dmin in four patients, but MLL amplification was not seen. Spectral karyotyping showed that the dmin derived from chromosome 11 in one patient and from chromosome 19 in two others without MYC or MLL amplification; derivation from these chromosomes was confirmed by FISH with chromosome paint probes. The dmin of chromosome 11 origin hybridized to a bacterial artificial chromosome (BAC)
RP11
-112M22 that maps to 11q24.3 and is predicted to contain ETS1 and other markers, including D11S11351 and D11S4091. The dmin of chromosome 19 origin in one patient hybridized to BACs
RP11
-46I12 and
RP11
-110J19; in the other patient, these clones did not hybridize with the dmin, but were found to be amplified on a marker chromosome that was derived from chromosome 19 in that patient's cells. These BACs have been mapped to 19q12-19q13.1 and 19q11-19q13.1, respectively, and are predicted to contain the markers D19S409 and D19S919 and the gene for ubiquinol-cytochrome C reductase, Rieske iron-sulfur polypeptide1 (UQCRFS1). dmin originating from chromosome 19 have not been reported previously in hematologic malignancies.
...
PMID:Double minute chromosomes in acute myeloid leukemia and myelodysplastic syndrome: identification of new amplification regions by fluorescence in situ hybridization and spectral karyotyping. 1192 Dec 81
Polycomb group proteins are implicated in embryogenesis and carcinogenesis through transcriptional regulation of target genes. ASXL1 and ASXL2 genes, encoding Polycomb group protein with ASXN and ASXM domains, are human homologs of Drosophila additional sex combs (asx) gene. Exons 2-13 of the ASXL2 gene are fused to exons 1-14 of the MYST3 gene in a case of therapy-related
myelodysplastic syndrome
due to t(2;8)(p23.3;p11.2). Here, we identified the ASXL3 gene, a novel human homolog of Drosophila asx, by using bioinformatics. ASXL3 gene, consisting of 12 exons, was located within human genome sequences
RP11
-562H1 (AC023192.8),
RP11
-265C19 (AC090989.8), and
RP11
-470B24 (AC010798.9). Complete coding sequence of human ASXL3 cDNA was determined by assembling EST BE145544, exons 4-11, and 5'-truncated KIAA1713 cDNA (AB051500.2). Partial coding sequence of mouse Asxl3 cDNA was derived from 3'-truncated C230079D11 cDNA (AK082659.1). Human ASXL3 mRNA was expressed in pancreatic islet, testis as well as in neuroblastoma, head and neck tumor. Human ASXL3 protein (2248 aa) with ASXN, ASXM and PHD domains was the third member of the human ASXL family. The region between ASXM and PHD domains was divergent among ASXL family members. Proline-rich domain was located within the divergent region of ASXL3, but not within that of ASXL1 and ASXL2. ASXL3-DTNA locus at chromosome 18q12.1 and ASXL2-DTNB locus at 2p23.3 were paralogous regions within the human genome. ASXL3 was a predicted cancer-associated gene, just like ASXL1 and ASXL2. This is the first report on identification and characterization of the ASXL3 gene.
...
PMID:Identification and characterization of ASXL3 gene in silico. 1513 7
Chromosome abnormalities of 6q are not frequently observed in myeloid disorders. In this article, we report the incidence of these chromosome changes in childhood myeloid leukemia as 2%-4% based on the cytogenetic database of a single institution. We applied fluorescence in situ hybridization (FISH) to characterize precisely the types of 6q abnormalities in seven patients (six with acute myeloid leukemia and one with
myelodysplastic syndrome
). They carried various translocations involving different breakpoints in 6q, as confirmed by FISH using a whole-chromosome-6 paint. Four cases were reported as t(6;11), although the breakpoints varied. Among these, we identified a novel translocation, t(6;11)(q24.1;p15.5), in a patient with acute megakaryoblastic leukemia. Molecular cytogenetic studies using the PAC clone RP5-1173K1 localized the genomic breakpoint on chromosome 11 to within the NUP98 gene. The breakpoint on chromosome 6 was narrowed down to a 500-kb region between BAC clones
RP11
-721P14 and
RP11
-39H10. Reverse-transcription PCR was performed using a forward primer specific for NUP98 and a reverse primer for the candidate gene in the 500-kb interval in 6q. This experiment resulted in the identification of a new fusion between NUP98 and C6orf80. Further studies will aim to fully characterize C6orf80 and will elucidate the role of this new NUP98 fusion in myeloid leukemia.
...
PMID:Characterization of 6q abnormalities in childhood acute myeloid leukemia and identification of a novel t(6;11)(q24.1;p15.5) resulting in a NUP98-C6orf80 fusion in a case of acute megakaryoblastic leukemia. 1602 18
Rearrangements of 6p are frequent in both myeloid and lymphoid malignant hematological disorders. High-mobility group AT-hook 2 (HMGA2) rearrangements have been described in myelofibrosis with myeloid metaplasia (MMM) and also in
myelodysplasia
. High-mobility group A proteins are nonhistone nuclear proteins that bind DNA and regulate the transcriptional activity of many genes. We used FISH, with bacterial artificial chromosome
RP11
-513I15 probe, to study 16 cases of myeloid malignancies with chromosome 6 short arm rearrangements, most of them following myeloproliferative disorders. Among these we found two 6p21.3 duplications and one 6p21.3 triplication involving HMGA1 in four cases of
myelodysplasia
with and without myelofibrosis. In these four cases, duplications and triplication were partially masked at the cytogenetic level by a derivative chromosome 6 resulting from translocation with another chromosome. HMGA1 proteins have been recently found overexpressed in human leukemias, but to our knowledge this is the first reported duplication of HMGA1.
...
PMID:Cryptic 6p21.3 duplications and triplication involving HMGA1 partially masked by add 6p in four cases of myelodysplasia. 1636 69
TET2 haplo-insufficiency occurs through different molecular mechanisms and is promptly revealed by array comparative genomic hybridization, single nucleotide polymorphism (SNP) array, and next-generation sequencing (NGS). Fluorescence in situ hybridization (FISH) can effectively demonstrate TET2 deletions and is often used to validate molecular results. In the present study 41
MDS
patients with and without 4q abnormalities were analyzed with a series of bacterial artificial chromosome (BAC) probes spanning the 4q22.3-q25 region. On conventional cytogenetic (CC) studies, a structural defect of the long arm of chromosome 4 (4q) was observed in seven patients. In three, one each with a t(1;4)(p21;q24), an ins(5;4)(q23;q24qter), and a t(4;17)(q31;p13) as the sole chromosomal abnormality, FISH with the
RP11
-356L5 and
RP11
-16G16 probes, which cover the TET2 locus, produced one signal only. Unexpectedly, this same result was achieved in 3 of the remaining 34 patients. Thus, a TET2 deletion was observed in a total of six patients (14.6%). TET2 deletion was not correlated with any particular clinical findings or outcome. These findings demonstrate that 1) FISH is an effective and economical method to reveal cryptic abnormalities of band 4q22-q24 resulting in TET2 deletions; 2) in these patients, TET2 deletion is the unifying genetic event; and 3) the different breakpoints within the 4q22-q25 region suggest that deletions are not mediated by repetitive sequences.
...
PMID:Detection of TET2 abnormalities by fluorescence in situ hybridization in 41 patients with myelodysplastic syndrome. 2274 34
Acute myeloid leukemia (AML) represents 80% of adult leukemias and 15-20% of childhood leukemias. AML are characterized by the presence of 20% blasts or more in the bone marrow, or defining cytogenetic abnormalities. Laboratory diagnoses of
myelodysplastic syndromes
(
MDS
) depend on morphological changes based on dysplasia in peripheral blood and bone marrow, including peripheral blood smears, bone marrow aspirate smears, and bone marrow biopsies. As leukemic cells are not functional, the patient develops anemia, neutropenia, and thrombocytopenia, leading to fatigue, recurrent infections, and hemorrhage. The genetic background and associated mutations in AML blasts determine the clinical course of the disease. Over the last decade, non-coding RNAs transcripts that do not codify for proteins but play a role in regulation of functions have been shown to have multiple applications in the diagnosis, prognosis and therapeutic approach of various types of cancers, including myeloid malignancies. After a comprehensive review of current literature, we found reports of multiple long non-coding RNAs (lncRNAs) that can differentiate between AML types and how their exogenous modulation can dramatically change the behavior of AML cells. These lncRNAs include: H19, LINC00877,
RP11
-84C10, CRINDE, RP11848P1.3, ZNF667-AS1, AC111000.4-202, SFMBT2, LINC02082-201, MEG3, AC009495.2, PVT1, HOTTIP, SNHG5, and CCAT1. In addition, by performing an analysis on available AML data in The Cancer Genome Atlas (TCGA), we found 10 lncRNAs with significantly differential expression between patients in favorable, intermediate/normal, or poor cytogenetic risk categories. These are: DANCR, PRDM16-DT, SNHG6, OIP5-AS1, SNHG16, JPX, FTX, KCNQ1OT1, TP73-AS1, and GAS5. The identification of a molecular signature based on lncRNAs has the potential for have deep clinical significance, as it could potentially help better define the evolution from low-grade
MDS
to high-grade
MDS
to AML, changing the course of therapy. This would allow clinicians to provide a more personalized, patient-tailored therapeutic approach, moving from transfusion-based therapy, as is the case for low-grade
MDS
, to the introduction of azacytidine-based chemotherapy or allogeneic stem cell transplantation, which is the current treatment for high-grade
MDS
.
...
PMID:Long Non-coding RNAs in Myeloid Malignancies. 3168 86
