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GATA1 Mutations in Transient Leukemia and Myeloid Leukemia in “Down” Syndrome.

Reinhardt, Katarina ; Boehmer, Katarina ; Klusmann, Jan-Henning ; [et al.]

American Society of Hematology ; 2008

In: Blood Vol. 112, No. 11 ( 2008-11-16), p. 923-923

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In: Blood, American Society of Hematology, Vol. 112, No. 11 ( 2008-11-16), p. 923-923

Abstract: Introduction: Newborns with trisomy 21 have a 5 to 10% risk to develop transient leukemia (TL). More than 20% of these infants progress to myeloid leukemia of Down syndrome (ML-DS) within the first 4 years of life. Mutations of the hematopoietic transcription factor GATA1 have been identified in almost all patients with TL and ML-DS. Here we report the biological and follow up data of a large cohort of children with proven GATA1 mutation reported to date either as TL (n=43) or ML-DS (n=28). Results: GATA1 mutations (point mutations, insertion, deletion, duplication; including 45 mutations not yet published) were identified in 42/43 TL (98%) and in 23/28 ML-DS (83%) patients. n age madian gastation week WBC/μl blasts % outcome 1PB: peripheral blood; BM: bone marrow transient leukemia 43 3 days (0 to 57) 37 (31 to 40) 33450 (1000 to 321000) 45 (7 to 91) death n = 3, 7%  ML-DS n = 9, 22% ML-DS 28 1-3 yrs (0.8 to 3) 38 (37 to 38) 4900 (1000 to 160000) PB1 7(1-87)  BM1 24 (4-78) death n = 2, 7%  relapse n=0 In 9 patients multiple mutations were noted in the same clone as confirmed by subcloning. In one patient with TL two different GATA1 mutations were detected in two independent clones. When this patient progressed to ML-DS only the minor clone was present. The majority of the mutations was localized in exon 2 (n=59). Only a few mutations could be found in intron 1 and 2 (n=5) or in exon 3 (n=1). As a result, these mutations led to the introduction of a premature stop codon within exon 2 (n=40), frameshift (n=14), altered splicing (n=7), or lack of an initiation codon (n=4). Interestingly, children with TL and splicing mutations were significantly older at diagnosis than patients with other mutations (day 38 vs. day 3 p 〈 0.05). No differences between mutational types were evident regarding gestational age, white blood cell count, platelet count, hemoglobin levels, or risk of death or ML-DS. In children with a myeloproliferative disease (MPD; n=7) or acute megakaryoblastic leukemia (AMKL; n=1) without stigmata of Down syndrome, GATA1 mutations could be detected. All of them were diagnosed as trisomy 21 mosaic. In this group the frequency of frameshift and altered splice mutations (5/7 vs. 9/36) was significantly higher compared to those with premature stop codons (2/7 vs. 27/36); pFishers exact =0.03). In 20 children (TL n=13, ML-DS n=7) the GATA1 mutant clone has been prospectively monitored by quantitative PCR using patient specific TaqMan probes. Seventeen TL patients showed decreasing minimal residual disease (MRD) levels and became negative ( 〈 10−4) during follow-up, whereas three children, who later developed ML-DS, remained positive at all time points. After two treatment elements all ML-DS patients had undetectable levels of GATA1s. After a median follow up of 1.5 years (0.9 to 2 years), no child suffered relapse however, the follow-up is much too short to draw definitive conclusions. Conclusion: In conclusion, we confirmed the high frequency of GATA1 mutations in children with TL or ML-DS. The occurrence of splicing mutations correlated with the age at diagnosis underlining the biologic relevance of the kind of mutation. We demonstrated the feasibility of a leukemia specific monitoring of MRD. As those children with sustaining detectable levels of GATA1s progressed to leukemia, these results might have therapeutic consequences for TL and later for ML-DS. In addition it may serve as a proof of principle for the feasibility of MRD monitoring in other AML-associated mutations. The identification of GATA1s positive MPD and AMKL in children without obvious stigmata of Down syndrome, all confirmed as trisomy 21 mosaic, implicate the necessity of GATA1s diagnostics in all newborn and infants with megakaryoblastic leukemia.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V112.11.923.923

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Language: English

Publisher: American Society of Hematology

Publication Date: 2008

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Is Prevention of Myeloid Leukemia Possible?.

Reinhardt, Katarina ; Blink, Marjolein ; Sander, Annette ; [et al.]

American Society of Hematology ; 2009

In: Blood Vol. 114, No. 22 ( 2009-11-20), p. 481-481

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In: Blood, American Society of Hematology, Vol. 114, No. 22 ( 2009-11-20), p. 481-481

Abstract: Abstract 481 Childhood leukemia frequently originates prenatally. Only a small percentage ( 〈 1%) of children with recurrent leukemia associated aberrations detected at birth suffer leukemia later on. In addition, no option to treat the preleukemic clone is availabel. Therefore, neither general screening at birth is useful nor preemptive treatment is possible. The high incidence (5 to 10%) of the transient leukemia (TL) in newborns with trisomy 21 and the high risk to develop a myeloid leukemia of Down Syndrome (ML-DS) within the first 4 years of life supported the hypothesis that the elimination of the preleukemic GATA1 positive clone might prevent leukemia. Prerequisites are the high sensitivity of TL-blasts to cytarabine, the recurrence of the same GATA1-mutated clone and the feasibility to monitor the preleukemic clone. Since 4/2007 69 children with TL were enrolled the study “Prevention of Myeloid Leukemia in Children with Down Syndrome and Transient Leukemia” (EudraCT 2006-002962-20) ; Germany n=50, The Netherlands n=16, Slovakia n=1, Czech Republic n=2). Inclusion criteria were met by 52 children (study patients), 17 children were observed only (protocol patients). Table 1 summarizes the patients' characteristics. The TL and ML-DS specific mutations of the transcriptions factor GATA1 have been detected in 60 children (87%), failure of detection were caused by low percentage of blasts ( 〈 2%) combined with late diagnosis (≥20 days after birth). The median follow-up within the study group was 1 year (0.2 to 2.3 years). Totally, 58 % of the children showed clinical symptoms associated to the TL, severe complications have been reported in 22 children (table 2). According to the study guidelines 20 out of these 22 children were treated with low dose cytarabine (1.5mg/kg body weight 1 week). Enrollment to the study including reference diagnostics and consulting, and a consequent treatment seems to improve the prognosis of this particular group. Compared to the historical group of children with similar characteristics (Klusmann et al. Blood 111(6):2991-8, 2008), the overall survival (2 years) significantly increased from 55±7% to 84±8%, p=0.03. MRD diagnostics by qRT-PCR and/or immunophenotyping was performed in 53 children (77%). Reasons for failure were early deaths (n=9; cardiac defects n=1, prematurity/MOV n=7, liver fibrosis n=1), refusal of monitoring by the parents (n=3), lack of material (n=4). If the MRD-level at week 8 and/or 10 exceeded 10-3 (qRT-PCR) or 10-2 (immunophenotyping), respectively, intervention with low-cytarabine was recommended. Currently, 39 children were already analyzed at week 12 (1st endpoint). In 7 children (13%) treatment recommendation according to high MRD levels were given. With exception of transient myelosuppression (CTC Grade II) no severe side effects occurred. All children but two became MRD negative at week 12. To date one child with persistent detectable MRD levels suffered ML-DS (1 year after TL). In summary, participating in the study and treatment of children with TL causing severe clinical symptoms seems to improve the prognosis. Although the recruitment into the study is faster than expected and the results to date are promising, the follow-up is much too short to draw definitive conclusion. Disclosures: No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V114.22.481.481

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Language: English

Publisher: American Society of Hematology

Publication Date: 2009

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GATA1 Mutation In Transient Leukemia (TL) and Myeloid Leukemia of Down Syndrome

Reinhardt, Katarina ; Kate, Alford ; Bohmer, Katarina ; [et al.]

American Society of Hematology ; 2010

In: Blood Vol. 116, No. 21 ( 2010-11-19), p. 1725-1725

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In: Blood, American Society of Hematology, Vol. 116, No. 21 ( 2010-11-19), p. 1725-1725

Abstract: Abstract 1725 Children up to the age of 5 years with trisomy 21 (T21, Down Syndrome) are at a 400-fold excess risk of developing myeloid leukemia (ML-DS). ∼5% of newborns with T21 develop a transient leukemia (TL). The megakaryoblastic phenotype by morphology and immunophenotyping is similar in both leukemias. Mutations in hematopoietic transcription factor GATA1 gene leading to expression of N-terminal truncated protein (GATA1s) have been detected in almost all TL and ML-DS patients and is the diagnostic genetic hallmark of these diseases. Aims: Fast and accurate identification is required to:confirm the diagnosis of TL or ML-DSconfirm the diagnosis of a GATA1s positive leukemia in children with no or little stigmata of Down Syndrome (T21 mosaic)monitor minimal residual disease (MRD)determine the pattern of GATA1 mutation in TL and ML-DS. Patients: Here we report the largest cohort of children (n=229) with TL (n=129) and ML-DS (n=100). The blast percentage of blasts were significant different (TL 43±3% vs. ML-DS 29 ±2%, p 〈 0.03). Methods: The GATA1 mutation screening have been performed in two laboratories, the central reference of the AML-BFM Study Group (Hannover, Germany; TL n=90, ML-DS n=63) and at the Weatherall Institute of Molecular Medicine (Oxford, UK; TL n=39, ML-DS n=37). The AML-BFM Lab conducted direct sequencing. If this failed, sequencing was repeated with sorted blasts. If the result remained negative, subcloning of the blasts was performed (21 out of 137 patients). The Oxford lab screened all samples by WAVE and direct sequencing. The lower limit of blasts which allowed for successful detection of a GATA1 mutation was 2%. Results: GATA1 mutations were identified in 125 out of 129 (96%) newborns with TL and in 97/100 (97%) children with ML-DS. In 99% of cases GATA1 mutations were detected in exon 2; only in 2 cases were exon 3 mutations identified. GATA1 mutation were identified in 13 children with Down mosaic and acute leukemia (TL n=8; ML-DS n=5). The detection of GATA1 prevents intensive chemotherapy in newborns with TL and allowed reduced intensity chemotherapy to be administered in infants with ML-DS. The mutations are diverse: deletions (37%), point mutations (24%), duplications (23%) and insertions (16%). With exception of substitutions, which were uniquely detected in TL (n=2; 1.6%), no differences between TL and ML-DS have been observed. Mutations were predicted to result in a stop codon(66%), affect splicing (16%), produce a frameshift that produced a subsequent stop codon (7%), or alter the start codon (3%). No differences in these predicted outcomes was present between TL and DS-ML. Summary: Rapid detection of GATA1 mutations is possible in almost all children with T1 and mosaic T21 who develop TL or ML-DS with these approaches, even in samples where the blast count is as low as 2%. Mutation detection and conformation of the correct diagnosis is critical to ensure appropriate therapy is administered and to allow patient specific MRD monitoring. Disclosures: No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V116.21.1725.1725

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XA 33000

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XA 10000

Language: English

Publisher: American Society of Hematology

Publication Date: 2010

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Analysis of GATA1 mutations in Down syndrome transient myeloproliferative disorder and myeloid leukemia

Alford, Kate A. ; Reinhardt, Katarina ; Garnett, Catherine ; [et al.]

American Society of Hematology ; 2011

In: Blood Vol. 118, No. 8 ( 2011-08-25), p. 2222-2238

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In: Blood, American Society of Hematology, Vol. 118, No. 8 ( 2011-08-25), p. 2222-2238

Abstract: Children with Down syndrome (DS) up to the age of 4 years are at a 150-fold excess risk of developing myeloid leukemia (ML-DS). Approximately 4%-5% of newborns with DS develop transient myeloproliferative disorder (TMD). Blast cell structure and immunophenotype are similar in TMD and ML-DS. A mutation in the hematopoietic transcription factor GATA1 is present in almost all cases. Here, we show that simple techniques detect GATA1 mutations in the largest series of TMD (n = 134; 88%) and ML-DS (n = 103; 85%) cases tested. Furthermore, no significant difference in the mutational spectrum between the 2 disorders was seen. Thus, the type of GATA1 sequence mutation is not a reliable tool and is not prognostic of which patients with TMD are probable to develop ML-DS.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood-2011-03-342774

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XA 33000

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Language: English

Publisher: American Society of Hematology

Publication Date: 2011

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GATA1s Induces Hyperproliferation of Eosinophil Precursors.

Maroz, Aliaksandra ; Reinhardt, Katarina ; Hitzler, Johann K. ; [et al.]

American Society of Hematology ; 2012

In: Blood Vol. 120, No. 21 ( 2012-11-16), p. 2318-2318

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In: Blood, American Society of Hematology, Vol. 120, No. 21 ( 2012-11-16), p. 2318-2318

Abstract: Abstract 2318 Transient leukemia (TL) is evident in 5–10% of all neonates with Down syndrome (DS) and closely linked to characteristic N-terminal truncating GATA1-mutations (GATA1s). Here we investigated the relationship between GATA1s-mutation and clonal eosinophilia observed in a cohort of TL patients (23%, n=60 DS neonates diagnosed with TL). TL-blasts exhibited an activated eosinophilic genetic program (as demonstrated by GSEA and validated by qRT-PCR) and had an increased propensity to differentiate along the eosinophilic lineage in vitro. Sorted patient TL-eosinophils carried the same mutation in GATA1 as the TL-blasts showing their clonal origin. To delineate the role of GATA1s in the TL-associated eosinophilia, we examined the myeloid differentiation of human fetal hematopoietic progenitors ectopically expressing GATA1 or GATA1s. We used a modified lentiviral LeGO-iG vector simultaneously expressing murine Gata1s or full-length Gata1 and an shRNA against endogenous GATA1 (65% knockdown efficiency, p 〈 0.05), ensuring the investigation of the net effect of GATA1s in cells with low endogenous GATA1 expression. Ectopic expression of Gata1s in human CD34+ fetal hematopoietic stem and progenitor cells (HSPCs) induced 10-fold higher (p 〈 0.01) proliferation rate of granulated progenitor cells in the myeloid in vitro differentiation medium accompanied by a monocytic differentiation block and reduction of neutrophils. In methylcellulose colony-forming assays, we observed formation of atypical colonies (29% of all CFUs), consisting of hyperproliferative myeloid progenitors with eosinophilic and basophilic granulation. These cells predominated in replating experiments, leading to a 15-fold higher cumulative number of CFUs after the fourth round of replating for Gata1s-transduced cells compared to the empty vector-transduced cells (p 〈 0.001). To elucidate the lineage nature of these myeloid progenitors, we used high throughput chip cytometry that allowed us to study expression of 20 surface and intracellular markers of the cells from a picked Gata1s-colony. We observed high expression of the early myeloid marker CD13 and of IL-3 receptor (CD123). In conjunction with histochemical stainings chip cytometry allowed us to exclude monocytic, erythroid, lymphoid and basophilic/mast cell origin of these cells as all markers for these lineages were low or absent. Global gene expression profiling using microarray technology of Gata1s-, Gata1- and empty vector-transduced HSPCs, grown for four days in the myeloid differentiation medium and of empty vector transduced cells, before we transferred them into the myeloid differentiation medium demonstrated enrichment (GSEA) of eosinophilic genes in Gata1- and Gata1s-transduced cells and downregulation of monocytic, neutrophil, basophil, mast cell and HSPC gene sets. Thus, global gene expression analyses, chip cytometry and histochemical methods identified Gata1s-transduced myeloid progenitors as atypical eosinophilic promyelocytes with abnormal pro-eosinophilic granulation. However, though GATA1s retained the function of GATA1 to promote differentiation of HSPCs along the eosinophil lineage while repressing the neutrophil/monocytic program, only Gata1s-transduced cells demonstrated a hyperproliferative phenotype. GSEA of known E2F-bound target genes and qRT-PCR validation demonstrated that, unlike Gata1, Gata1s was not able to repress a number of GATA1 target genes, such as MYC, and the pro-proliferative E2F transcription network perturbing the balance between differentiation and proliferation. This might result in the hyperproliferation of eosinophil precursors at the expense of the neutrophil/monocytic lineage. As E2F target genes were also upregulated in sorted TL-eosinophils (n=3), we propose the same molecular mechanism of GATA1s-induced clonal eosinophilia in TL. Disclosures: Hennig: European Patent Office: Patents & Royalties.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V120.21.2318.2318

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XA 33000

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Language: English

Publisher: American Society of Hematology

Publication Date: 2012

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Single Cell Whole Exome Sequencing in NPM1/Flt3 Positive Pediatric Acute Myeloid Leukemia

Walter, Christiane ; Hofmann, Winfried ; Reinhardt, Katarina ; [et al.]

American Society of Hematology ; 2014

In: Blood Vol. 124, No. 21 ( 2014-12-06), p. 1043-1043

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In: Blood, American Society of Hematology, Vol. 124, No. 21 ( 2014-12-06), p. 1043-1043

Abstract: Introduction: Acute myeloid leukemia (AML) is one of the most frequent forms of leukemia in children younger than 15 years. The detection of several mutations in a blast population of pediatric AML (pAML) is supposed to be caused by a clonal evolution from a leukemic stem cell (LSC) to leukemic blasts. LSC are believed to be more resistant to chemotherapy, to be able to survive during treatment and to be responsible for the emergence of a relapse due to the persistence in the bone marrow (BM) niche. Since LSC and potential leukemic subclones are only present in small subpopulations, it has been a major technical challenge to particular analyse only the specific population. To acquire a better understanding of the underlying mechanisms of mutagenesis, clonal evolution and leukemogenesis, the aim of this study was to establish methods that allow the analysis and detection of mutations in single cells of a subpopulation known to contain HSC as well as LSC (CD34+CD38-). We especially focused on a pAML subgroup with mutations in Nucleophosmin (NPM1) and/or fms related tyrosine kinase 3 (Flt3). Methods and Results: We established methods to perform single cell sorting, whole genome amplification (WGA) using multiple displacement amplification (MDA) technology (Qiagen) and subsequent whole exome sequencing. The sorting efficiency was checked as Hoechst stained cells were sorted onto glas slides with 48 defined spots and the presence of single cells was checked under an inverse fluorescent microscope. Subsequently, single CD34+CD38- patient derived cells were sorted into 0,5ml low binding tubes containing 4µl PBS followed by WGA and whole exome sequencing. The mutational status of the sorted single cells from three patients suffering from pAML was analysed and compared to mutations detected at initial diagnosis in DNA from a bulk of BM cells. WGA from single CD34+CD38-PI- cells resulted in an amount of 29 to 31.7µg DNA from each of five single cells. The quality of the amplified DNA was sufficient for whole exome sequencing. A 4bp insertion in exon 12 of NPM1 reflecting a common NPM1 mutation (MutA) initially detected from a bulk of cells was identified in amplified DNA from single cells using whole exome sequencing in 2/3 patients. Internal tandem duplications in Flt3 indicated by mismatches in the alignment could be detected in amplified DNA from single cells of two patients. The detected ITD resemble those initially detected in DNA from a bulk of BM cells. Discussion and Conclusion: Single cell sequencing provides a useful tool to amend the detection of genetic aberrations from a bulk of cells and to confirm the presence of specific mutations in single cells from small subpopulations. It therefore helps to get further insights into the clonal evolution in pAML. Disclosures No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V124.21.1043.1043

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Language: English

Publisher: American Society of Hematology

Publication Date: 2014

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Treatment and prognostic impact of transient leukemia in neonates with Down syndrome

Klusmann, Jan-Henning ; Creutzig, Ursula ; Zimmermann, Martin ; [et al.]

American Society of Hematology ; 2008

In: Blood Vol. 111, No. 6 ( 2008-03-15), p. 2991-2998

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In: Blood, American Society of Hematology, Vol. 111, No. 6 ( 2008-03-15), p. 2991-2998

Abstract: Approximately 10% of the neonates with Down syndrome (DS) exhibit a unique transient leukemia (TL). Though TL resolves spontaneously in most patients, early death and development of myeloid leukemia (ML-DS) may occur. Prognostic factors as well as treatment indication are currently uncertain. To resolve that issue, we prospectively collected clinical, biologic, and treatment data of 146 patients with TL. The 5-year overall survival (OS) and event-free survival (EFS) were 85% plus or minus 3% and 63% plus or minus 4%, respectively. Multivariate analysis revealed a correlation between high white blood cell (WBC) count, ascites, preterm delivery, bleeding diatheses, failure of spontaneous remission, and the occurrence of early death. Treatment with cytarabine (0.5-1.5 mg/kg) was administered to 28 patients with high WBC count, thrombocytopenia, or liver dysfunction. The therapy had a beneficial effect on the outcome of those children with risk factors for early death (5-year EFS, 52% ± 12% vs 28% ± 11% [no treatment]; P = .02). Multivariate analysis demonstrated its favorable prognostic impact. A total of 29 (23%) patients with TL subsequently developed ML-DS. Patients with ML-DS with a history of TL had a significantly better 5-year EFS (91% ± 5%) than those without documented TL (70% ± 4%), primarily due to a lower relapse rate. A history of TL may therefore define a lower-risk ML-DS subgroup. This study was registered at www.clinicaltrials.gov as no. NCT 00111345.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood-2007-10-118810

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Language: English

Publisher: American Society of Hematology

Publication Date: 2008

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Low-dose cytarabine to prevent myeloid leukemia in children with Down syndrome: TMD Prevention 2007 study

Flasinski, Marius ; Scheibke, Kira ; Zimmermann, Martin ; [et al.]

American Society of Hematology ; 2018

In: Blood Advances Vol. 2, No. 13 ( 2018-07-10), p. 1532-1540

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In: Blood Advances, American Society of Hematology, Vol. 2, No. 13 ( 2018-07-10), p. 1532-1540

Abstract: Low-dose cytarabine treatment reduced mortality in symptomatic TMD patients compared with the historical control. An MRD monitoring–based low-dose cytarabine treatment does not prevent progression from preleukemic TMD to ML-DS.

Type of Medium: Online Resource

ISSN: 2473-9529 , 2473-9537

URL: Article

DOI: 10.1182/bloodadvances.2018018945

Language: English

Publisher: American Society of Hematology

Publication Date: 2018

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Next Generation Sequencing for Minimal Residual Disease Monitoring in AML Patients with FLT3-ITD,

Thol, Felicitas ; Damm, Frederik ; Wagner, Katharina ; [et al.]

American Society of Hematology ; 2011

In: Blood Vol. 118, No. 21 ( 2011-11-18), p. 3548-3548

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In: Blood, American Society of Hematology, Vol. 118, No. 21 ( 2011-11-18), p. 3548-3548

Abstract: Abstract 3548 Minimal Residual Disease (MRD) monitoring has become an important tool for risk and treatment stratification in hematological malignancies. MRD monitoring in FLT3 mutated patients has been difficult in the past as FLT3-ITDs vary from patient to patient and individual primer/probe sets would be required to assess MRD over time. In the present study we evaluated next-generation sequencing (NGS) as a new tool for MRD monitoring in patients with FLT3-ITD and NPM1 mutations. Five pediatric and 5 adult AML patients with FLT3-ITD and 10 adult patients with NPM1 mutations were analyzed by NGS with a target coverage of 10,000 reads per amplicon. Pediatric samples were collected at diagnosis, day 22 and after consolidation chemotherapy while adult samples were collected at different time points (average 4 timepoints per patient). Samples were sequenced unidirectionally on eight-lane PicoTiterPlates on a GS FLX sequencing system. In total, 2,563,550 sequencing reads were generated, corresponding to a total of 1,176,171 high-quality sequencing reads. NPM1 mutations were analyzed by quantitative RT-PCR using the MutaQuant kit from Ipsogen (Ispogen, Marseille, France). Allelic ratios of FLT3-ITDs were determined by fragment analysis on a DNA sequencer using GeneMapper software 4.0. First, the sensitivity of NGS to detect mutated alleles was evaluated by sequencing serial dilutions of a patient sample that had 46.3 percent mutated FLT3-ITD alleles at diagnosis. With a target coverage of 10,000 sequences and an allelic ratio of 46.3 percent the theoretical detection sensitivity was at most 1 in 4630 sequences. In fact, the allelic ratio in the sequenced samples linearly decreased in the tested dilutions down to the 5×10-4 dilution (Pearson correlation R2=.996). Samples from healthy volunteers were tested negative for both FLT3-ITD and NPM1 mutations (n=3). Allelic ratios from three diagnostic specimens of FLT3-ITD mutated patients were highly reproducible when determined in two independent NGS runs. As proof of principle we analyzed NPM1 mutated patients by NGS and quantitative RT-PCR in parallel. The mean allelic ratio of NPM1 mutants at diagnosis was 0.37 (range 0.29–0.46). An allelic ratio of 0.37 and 0.4 was measured in peripheral blood of two patients, and thus was similar to ratios in bone marrow. Concordant results between NGS and qRT-PCR were found in 38 samples (95%), whereas in two samples one method did not detect the mutation while the other did (NGS and RT-PCR were negative once each). We analyzed relapse samples in four patients. The NPM1 mutation was detected consistently by both methods in three patients at allelic ratios of 0.013, 0.19, and 0.32, while one patient had lost the mutation at relapse. One patient had an atypical NPM1 mutation for which no RT-PCR kit was available. NGS allowed quantification of the allelic ratio in this patient, which was 0.37 at diagnosis, 0.06 after one cycle of induction therapy, and 0 after the second cycle of induction therapy. In FLT3-ITD mutated patients we could determine insertion site, insertion length, number of individual clones, and allelic ratio from NGS data. The mean allelic ratio in diagnostic samples was 0.27 as measured by NGS and 0.4 as measured by fragment analysis. Three follow up samples were negative by fragment analysis, while a small clone could still be detected with NGS in these samples (allelic ratio 0.0004 to 0.001). All other samples were concordant between fragment analysis and NGS. NGS was used to determine MRD status in 5 patients with childhood AML harboring mutated FLT3. A reduction of 2–3 orders of magnitude was achieved during induction chemotherapy. During consolidation a further decrease or disappearance of mutated alleles was achieved in 3 patients, who remained in remission. However, allelic burden increased in 2 patients after first consolidation treatment (HAM) by 9- and 735-fold compared to the allelic ratio after induction therapy, and they relapsed 74 and 303 days later. Thus, accurate determination of the FLT3-ITD allelic ratio by NGS may become useful to identify patients before overt relapse. In summary, we show that NGS can be used for minimal residual disease assessment in FLT3-ITD mutated AML patients. The sensitivity of the method is scalable depending on the read depth, however, an adequate sensitivity level for efficient MRD detection still needs to be determined. Disclosures: No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V118.21.3548.3548

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Language: English

Publisher: American Society of Hematology

Publication Date: 2011

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Single‐cell whole exome and targeted sequencing in NPM1/FLT3 positive pediatric acute myeloid leukemia

Walter, Christiane ; Pozzorini, Christian ; Reinhardt, Katarina ; [et al.]

Wiley ; 2018

In: Pediatric Blood & Cancer Vol. 65, No. 2 ( 2018-02)

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In: Pediatric Blood & Cancer, Wiley, Vol. 65, No. 2 ( 2018-02)

Abstract: The small portion of leukemic stem cells (LSCs) in acute myeloid leukemia (AML) present in children and adolescents is often masked by the high background of AML blasts and normal hematopoietic cells. The aim of the current study was to establish a simple workflow for reliable genetic analysis of single LSC‐enriched blasts from pediatric patients. Procedure For three AMLs with mutations in nucleophosmin 1 and/or fms‐like tyrosine kinase 3, we performed whole genome amplification on sorted single‐cell DNA followed by whole exome sequencing (WES). The corresponding bulk bone marrow DNAs were also analyzed by WES and by targeted sequencing (TS) that included 54 genes associated with myeloid malignancies. Results Analysis revealed that read coverage statistics were comparable between single‐cell and bulk WES data, indicating high‐quality whole genome amplification. From 102 single‐cell variants, 72 single nucleotide variants and insertions or deletions (70%) were consistently found in the two bulk DNA analyses. Variants reliably detected in single cells were also present in TS. However, initial screening by WES with read counts between 50–72× failed to detect rare AML subclones in the bulk DNAs. Conclusions In summary, our study demonstrated that single‐cell WES combined with bulk DNA TS is a promising tool set for detecting AML subclones and possibly LSCs.

Type of Medium: Online Resource

ISSN: 1545-5009 , 1545-5017

URL: Issue

URL: Article

DOI: 10.1002/pbc.v65.2

DOI: 10.1002/pbc.26848

Language: English

Publisher: Wiley

Publication Date: 2018

detail.hit.zdb_id: 2130978-4

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