Fernando P.G. Silva scite author profile

Based on our previous results indicating the presence of a tumor suppressor gene (TSG), chromosome 21 was analysed for loss of heterozygosity (LOH) in 18 patients with acute myeloid leukemia (17, AML-M0; one, AML-M1). Allelotyping at polymorphic loci was performed on purified material, allowing unequivocal detection of allelic loss and homozygous deletions. Six AML-M0 patients shared a common region of LOH harboring a single gene: RUNX1 (AML1), the most frequent site of translocations in acute leukemia and a well-known fusion oncogene. Fluorescence in situ hybridization allowed the identification of deletions with breakpoints within RUNX1 in two patients as the cause of LOH. In the four others the LOH pattern and the presence of two karyotypically normal chromosomes 21 were in line with mitotic recombination. Further molecular and cytogenetic analyses showed that this caused homozygosity of primary RUNX1 mutations: two point mutations, a partial deletion and, most significantly, a complete deletion of RUNX1. These findings identify RUNX1 as a classical TSG: both alleles are mutated or absent in cancer cells from four of the 17 AML-M0 patients examined. In contrast to AML-M0, the AML-M1 patient was trisomic for chromosome 21 and has two mutated and one normal RUNX1 allele, suggesting that the order of mutagenic events leading to leukemia may influence the predominant tumor type.

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Gene expression profiling of minimally differentiated acute myeloid leukemia: M0 is a distinct entity subdivided by RUNX1 mutation status

Silva

Swagemakers²,

Erpelinck-Verschueren

et al. 2009

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Minimally differentiated acute myeloid leukemia (AML-M0) is defined by immature morphology and expression of early hematologic markers. By gene expression profiling (GEP) and subsequent unsupervised analysis of 35 AML-M0 samples and 253 previously reported AML cases, we demonstrate that AML-M0 cases express a unique signature that is largely separated from other molecular subtypes. Hematologic transcription regulators such as CEBPA, CEBPD, and ETV6, and the differentiation associated gene MPO appeared strongly down-regulated, in line with the primitive state of this leukemia. AML-M0 frequently carries loss-of-function RUNX1 mutation. Unsupervised analyses revealed a subdivision between AML-M0 cases with and without RUNX1 mutations. RUNX1 mutant AML-M0 samples showed a distinct up-regulation of B cell-related genes such as members of the B-cell receptor complex, transcription regulators RUNX3, ETS2, IRF8, or PRDM1, and major histocompatibility complex class II genes. Importantly, prediction with high accuracy of the AML-M0 subtype and prediction of patients carrying RUNX1 mutation within this subtype were possible based on the expression level of only a few transcripts. We propose that RUNX1 mutations in this AML subgroup cause lineage infidelity, leading to aberrant coexpression of myeloid and B-lymphoid genes. Furthermore, our results imply that AML-M0, although originally determined by morphology, constitutes a leukemia subgroup.

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Trisomy 13 correlates with RUNX1 mutation and increased FLT3 expression in AML-M0 patients

Silva¹,

Lind²,

Brouwer-Mandema³

et al. 2007

Haematologica

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Genome wide molecular analysis of minimally differentiated acute myeloid leukemia

et al. 2009

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ETV6 mutations and loss in AML-M0

et al. 2008

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individuals. This was performed in a number of studies for flow cytometry (Kern et al.; 6 San Miguel et al. Instead, we look at bone marrows that are regenerating after heavy chemotherapy. The expression of presumed leukemiaspecific genes or the frequency of presumed leukemia specific phenotypes can be very different in such samples compared to steady-state healthy bone marrow.For instance, the gene CSPG4 was identified as a possible MRD marker. 4 It was highly expressed in AML samples but not in healthy bone marrow. However, we found that it was useless as an MRD marker because expression of CSPG4 was also high in bone marrow that was free of leukemia but was regenerating after chemotherapy. 4 Therefore, to determine the real sensitivity and specificity of an MRD analysis, it is mandatory to analyze a large number of leukemia-free, regenerating bone marrows.A second problem of analyzing serial dilutions of leukemic cells in samples of healthy bone marrow is that this does not really simulate the situation of minimal residual disease. The important clinical question is the amount of leukemic stem cells that is still present in the patient. If the leukemic phenotype that is used for flow cytometry is present on the majority of leukemic cells but not on leukemic stem cells, the sensitivity could be lower than anticipated. If the expression of a leukemia-associated gene, like WT1, is particularly high in leukemic stem cells, the sensitivity might be much better than anticipated and vice versa. ConclusionsMonitoring MRD has become a strong diagnostic tool in acute leukemia. It is widely used for clinical decision-making in acute lymphoblastic leukemia, chronic myeloid leukemia and acute promyelocytic leukemia. Various methods have been developed to monitor MRD in AML and we should proceed to put them into clinical practice.Sensitivity is an important issue in the comparison of these methods. When the term is used, it should always be clear whether we are talking about the LPT or the real sensitivity and specificity of our diagnostic test.The LPT is easy to determine and for most methods of monitoring MRD, is in the range of 10 À4 -10 À6 . These figures have a very limited meaning because for clinical decisionmaking LPT cannot be used as the cutoff for high versus low MRD. At such a low threshold, the specificity of monitoring MRD (likelihood of a negative test result in a truly negative patient) is too low due to false positive healthy and regenerating bone marrows.If we use, for instance, a threshold of 10 À3 for clinical decision-making, it does not matter whether the LPT is 10 À4 or 10 À6 . What really matters is the sensitivity and specificity of the diagnostic test at the threshold of 10 À3 . We should put less effort into determining LPTs and more effort into determining sensitivity and specificity of our methods at the clinically relevant thresholds.Because of the many issues that influence the quality of each method of monitoring MRD, the best way of really comparing two methods is to simultaneously apply ...

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