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Literature DB >> 19152102

Differential gene expression of bone marrow-derived CD34+ cells is associated with survival of patients suffering from myelodysplastic syndrome.

Wolf C Prall^1,2, Akos Czibere^3,4, Franck Grall⁴, Dimitrios Spentzos⁴, Ulrich Steidl⁵, Aristoteles Achilles Nikolaus Giagounidis⁶, Andrea Kuendgen³, Hasan Otu⁴, Astrid Rong³, Towia A Libermann⁴, Ulrich Germing³, Norbert Gattermann³, Rainer Haas³, Manuel Aivado^3,4.

Abstract

One feature of the molecular pathology of myelodysplastic syndromes (MDS) is aberrant gene expression. Such aberrations may be related to patient survival, and may indicate to novel diagnostic and therapeutic targets. Therefore, we aimed at identifying aberrant gene expression that is associated with MDS and patient survival. Bone marrow-derived CD34+ hematopoietic progenitor cells from six healthy persons and 16 patients with MDS were analyzed on cDNA macroarrays comprising 1,185 genes. Thereafter, our patients were followed-up for 54 months. We found differential expression of genes that were hitherto unrecognized in the context of MDS. Differential expression of 10 genes was confirmed by quantitative real-time RT-PCR. Hierarchical cluster analysis facilitated the separation of CD34+ cells of normal donors from patients with MDS. More importantly, it also distinguished MDS-patients with short and long survival. Scrutinizing our cDNA macroarray data for genes that are associated with short survival, we found, among others, increased expression of six different genes that encode the proteasome subunits. On the other hand, the most differentially down-regulated gene was IEX-1, which encodes an anti-apoptotic protein. We confirmed its decreased expression on RNA and protein level in an independent validation set of patient samples. The presented data broadens our notion about the molecular pathology of MDS and may lend itself to better identify patients with short survival. Furthermore, our findings may help to define new molecular targets for drug development and therapeutic approaches for patients with poor prognosis.

Entities: Disease Gene Species

Mesh：

Substances：

Year: 2009 PMID： 19152102 DOI： 10.1007/s12185-008-0242-9

Source DB: PubMed Journal: Int J Hematol ISSN： 0925-5710 Impact factor: 2.490

61 in total

1. Processing and quality control of DNA array hybridization data.

Authors: T Beissbarth; K Fellenberg; B Brors; R Arribas-Prat; J Boer; N C Hauser; M Scheideler; J D Hoheisel; G Schütz; A Poustka; M Vingron
Journal: Bioinformatics Date: 2000-11 Impact factor: 6.937

2. Use of SMART-generated cDNA for differential gene expression studies.

Authors: M Herrler
Journal: J Mol Med (Berl) Date: 2000 Impact factor: 4.599

3. Frequent elevation of Akt kinase phosphorylation in blood marrow and peripheral blood mononuclear cells from high-risk myelodysplastic syndrome patients.

Authors: M Nyåkern; P L Tazzari; C Finelli; C Bosi; M Y Follo; T Grafone; P P Piccaluga; G Martinelli; L Cocco; A M Martelli
Journal: Leukemia Date: 2006-02 Impact factor: 11.528

Review 4. Gene expression profiling in the myelodysplastic syndromes.

Authors: Andrea Pellagatti; Carrie Fidler; James S Wainscoat; Jacqueline Boultwood
Journal: Hematology Date: 2005-08 Impact factor: 2.269

5. Excessive proliferation matched by excessive apoptosis in myelodysplastic syndromes: the cause-effect relationship.

Authors: A Raza; S Alvi; R Z Borok; L Span; A Parcharidou; D Alston; S Rifkin; E Robin; R Shah; S A Gregory
Journal: Leuk Lymphoma Date: 1997-09

6. Age-related transcription levels of KU70, MGST1 and BIK in CD34+ hematopoietic stem and progenitor cells.

Authors: Wolf C Prall; Akos Czibere; Marcus Jäger; Dimitrios Spentzos; Towia A Libermann; Norbert Gattermann; Rainer Haas; Manuel Aivado
Journal: Mech Ageing Dev Date: 2007-07-04 Impact factor: 5.432

7. Gene expression profiling in the myelodysplastic syndromes using cDNA microarray technology.

Authors: Andrea Pellagatti; Noor Esoof; Fiona Watkins; Cordelia F Langford; David Vetrie; Lisa J Campbell; Carrie Fidler; James D Cavenagh; Helen Eagleton; Peter Gordon; Barrie Woodcock; Beena Pushkaran; Mark Kwan; James S Wainscoat; Jacqueline Boultwood
Journal: Br J Haematol Date: 2004-06 Impact factor: 6.998

Review 8. Opportunities for Trisenox (arsenic trioxide) in the treatment of myelodysplastic syndromes.

Authors: A List; M Beran; J DiPersio; J Slack; N Vey; C S Rosenfeld; P Greenberg
Journal: Leukemia Date: 2003-08 Impact factor: 11.528

9. Cellular maturation in human preleukemia.

Authors: H P Koeffler; D W Golde
Journal: Blood Date: 1978-08 Impact factor: 22.113

10. High frequency of several PIG-A mutations in patients with aplastic anemia and myelodysplastic syndrome.

Authors: M Okamoto; T Shichishima; H Noji; K Ikeda; A Nakamura; K Akutsu; Y Maruyama
Journal: Leukemia Date: 2006-04 Impact factor: 11.528

11 in total

1. IER3 supports KRASG12D-dependent pancreatic cancer development by sustaining ERK1/2 phosphorylation.

Authors: Maria Noé Garcia; Daniel Grasso; Maria Belen Lopez-Millan; Tewfik Hamidi; Celine Loncle; Richard Tomasini; Gwen Lomberk; Françoise Porteu; Raul Urrutia; Juan L Iovanna
Journal: J Clin Invest Date: 2014-09-24 Impact factor: 14.808

2. Stress-induced hematopoietic failure in the absence of immediate early response gene X-1 (IEX-1, IER3).

Authors: Haley Ramsey; Qi Zhang; Diane E Brown; David P Steensma; Charles P Lin; Mei X Wu
Journal: Haematologica Date: 2013-09-20 Impact factor: 9.941

3. Resistance of Sézary cells to TNF-α-induced apoptosis is mediated in part by a loss of TNFR1 and a high level of the IER3 expression.

Authors: Oleg E Akilov; Mei X Wu; Irina V Ustyugova; Louis D Falo; Larisa J Geskin
Journal: Exp Dermatol Date: 2012-04 Impact factor: 3.960

4. Rearrangements and amplification of IER3 (IEX-1) represent a novel and recurrent molecular abnormality in myelodysplastic syndromes.

Authors: David P Steensma; Jessemy D Neiger; Julie C Porcher; J Jonathan Keats; P Leif Bergsagel; Thomas R Dennis; Ryan A Knudson; Robert B Jenkins; Rafael Santana-Davila; Rajiv Kumar; Rhett P Ketterling
Journal: Cancer Res Date: 2009-09-22 Impact factor: 12.701

Review 5. Immediate early response gene X-1, a potential prognostic biomarker in cancers.

Authors: Mei X Wu; Irina V Ustyugova; Liping Han; Oleg E Akilov
Journal: Expert Opin Ther Targets Date: 2013-02-04 Impact factor: 6.902

6. Expression of the runt homology domain of RUNX1 disrupts homeostasis of hematopoietic stem cells and induces progression to myelodysplastic syndrome.

Authors: Shinobu Matsuura; Yukiko Komeno; Kristen E Stevenson; Joseph R Biggs; Kentson Lam; Tingdong Tang; Miao-Chia Lo; Xiuli Cong; Ming Yan; Donna S Neuberg; Dong-Er Zhang
Journal: Blood Date: 2012-08-23 Impact factor: 22.113

7. Thrombopoietin promotes NHEJ DNA repair in hematopoietic stem cells through specific activation of Erk and NF-κB pathways and their target, IEX-1.

Authors: Bérengère de Laval; Patrycja Pawlikowska; Daniela Barbieri; Corinne Besnard-Guerin; Alba Cico; Rajiv Kumar; Murielle Gaudry; Véronique Baud; Françoise Porteu
Journal: Blood Date: 2013-11-01 Impact factor: 22.113