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Articles

Comprehensive genetic diagnosis of acute myeloid leukemia by next-generation sequencing

Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Databionics, Department of Mathematics and Informatics, Philipps-University Marburg, Germany
Department of Internal Medicine, Frankfurt (Oder) General Hospital, Frankfurt/Oder, Germany
Institute for Biomedical Aging Research, Leopold-Franzens-University Innsbruck, Austria
MLL, Munich Leukemia Laboratory, Germany
Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Department of Hematology, Oncology and Immunology, Philipps-University Marburg, and University Hospital Gießen and Marburg, Marburg, Germany
Vol. 104 No. 2 (2019): February, 2019 https://doi.org/10.3324/haematol.2018.194258

Abstract

Differential induction therapy of all subtypes of acute myeloid leukemia other than acute promyelocytic leukemia is impeded by the long time required to complete complex and diverse cytogenetic and molecular genetic analyses for risk stratification or targeted treatment decisions. Here, we describe a reliable, rapid and sensitive diagnostic approach that combines karyotyping and mutational screening in a single, integrated, next-generation sequencing assay. Numerical karyotyping was performed by low coverage whole genome sequencing followed by copy number variation analysis using a novel algorithm based on in silico-generated reference karyotypes. Translocations and DNA variants were examined by targeted resequencing of fusion transcripts and mutational hotspot regions using commercially available kits and analysis pipelines. For the identification of FLT3 internal tandem duplications and KMT2A partial tandem duplications, we adapted previously described tools. In a validation cohort including 22 primary patients’ samples, 9/9 numerically normal karyotypes were classified correctly and 30/31 (97%) copy number variations reported by classical cytogenetics and fluorescence in situ hybridization analysis were uncovered by our next-generation sequencing karyotyping approach. Predesigned fusion and mutation panels were validated exemplarily on leukemia cell lines and a subset of patients’ samples and identified all expected genomic alterations. Finally, blinded analysis of eight additional patients’ samples using our comprehensive assay accurately reproduced reference results. Therefore, calculated karyotyping by low coverage whole genome sequencing enables fast and reliable detection of numerical chromosomal changes and, in combination with panel-based fusion-and mutation screening, will greatly facilitate implementation of subtype-specific induction therapies in acute myeloid leukemia.

Introduction

Acute myeloid leukemia (AML) has recently been the object of thorough investigations at a molecular level, including whole genome next-generation sequencing (NGS) studies.1 According to current guidelines from the European Leukemia Network, recommended genetic testing in adult AML is predominantly directed towards risk stratification in order to identify an appropriate strategy for consolidation therapy.2 Genetic markers comprise t(8;21)(q22;q22.1)/RUNX1-RUNX1T1, inv(16)(p13.1q22) or t(16;16)(p13.1;q22)/CBFB-MYH11, t(15;17)/PML-RARA, t(9;11)(p21.3;q23.3)/MLLT3-KMT2A, other translocations involving the KMT2A gene, t(6;9)(p23;q34.1)/DEK-NUP214, inv(3)(q21.3;q26.2) or t(3;3)(q21.3;q26.2)/GATA2, MECOM, loss of chromosome 5/5q, 7, or 17/17p, mutations in CEPBA (biallelic), NPM1, RUNX1, ASXL1 and TP53, and internal tandem duplications (ITD) in the FLT3 gene.2 Additionally, AML with IDH2 mutations alone and AML with mutations in chromatin regulators or splicing factors such as DNMT3A, TET2, SRSF2 and SF3B1 have been proposed recently as distinct genomic subclasses of AML.3

In spite of the considerable genetic heterogeneity of the disease, chemotherapy with cytarabine and anthracyclines has been the backbone of induction treatment for adults with AML throughout the last 30 years.54 Only acute promyelocytic leukemia with the hallmark translocation t(15;17)/PML-RARA has been shown to be highly curable by all-trans retinoic acid and arsenic trioxide.6 Immediate chemotherapy-free first-line treatment of acute promyelocytic leukemia is possible because this specific entity can be diagnosed within just a few hours by peripheral blood smear or bone marrow cytology and targeted reverse transcriptase polymerase chain reaction (PCR) analysis for PML-RARA. In contrast, discrimination of all other AML subtypes requires multiple molecular and cytogenetic analyses. In particular, AML karyotyping often requires shipping of samples to specialized laboratories, thus precluding completion within 5-7 days, as recommended.2 Here, we developed and evaluated an integrated NGS platform for numerical karyotyping and focused screening for translocations and mutations in AML-related genes which enables fast identification of the majority of genetic alterations in AML with prognostic and therapeutic implications.

Methods

Patients and cell lines

The 33 patients’ samples analyzed in this study were obtained from the repository of the Clinic for Hematology, Oncology and Immunology or the Munich Leukemia Laboratory with the patients’ informed consent. Cell lines were purchased from DSMZ. This study was approved by the clinical ethics committee at the Faculty of Medicine, Philipps-University Marburg (N. 38/16).

Library preparation and sequencing

Whole genome libraries were constructed using the NEBNext Ultra II kit (New England Biolabs, Ipswich, MA, USA). Fusion libraries were prepared using the FusionPlex Heme v1 or v2 panels (ArcherDX, Boulder, CO, USA). Variant libraries were generated using the TruSight Myeloid panel (Illumina, San Diego, CA, USA) or the QIAseq™ Human Myeloid Neoplasms panel (Qiagen, Hilden, Germany). Sequencing was performed on an Illumina MiSeq instrument. The experimental procedures are detailed in the Online Supplementary Methods.

Bioinformatics

Copy number variations (CNV) were analyzed using a proprietary algorithm designated CAI[N] (chromosomal aberration identifier [numerical]) which was implemented in Python. Fusion calling was performed using the Archer Analysis pipeline (version 4.1). For variant calling, the BaseSpace TruSight Myeloid App (Illumina) and ITD-seek7 or, respectively, smCounter8 (Qiagen) were used as appropriate. For identification of KMT2A-partial tandem duplications (PTD) in amplicon libraries, a novel Python algorithm (PTDi: PTD identifier) was developed. Details are given in the Online Supplementary Methods.

Results

Design of an integrated next-generation sequencing platform for comprehensive genetic analyses in acute myeloid leukemia

Our NGS platform for comprehensive genetic characterization of AML samples was designed to enable fast and reliable detection of genetic aberrations that are of critical importance for diagnosis, prognosis and therapy in adult AML.931 The complete workflow including three NGS-library preparations and data analysis by five different algorithms can be completed within 5 days (Figure 1A).

Figure 1.Comprehensive genetic diagnosis of acute myeloid leukemia by next-generation sequencing. (A) Outline of the workflow: each sample is subjected to preparation of three sequencing libraries. Libraries are indexed separately for sequencing on the same flowcell. Data are analyzed using five distinct algorithms for the detection of CNV, fusions, and DNA variants. The whole workflow can be completed within 5 days if performed by one person; times to perform individual steps of the composite assay are indicated on the right. (B) Outline of the CAI[N] algorithm for CNV analysis. Reads are mapped to 1 Mb fixed genomic windows and read distributions are compared to the average of more than 2,500 normal karyotypes (Nfemale=2,819, Nmale=2,605) generated by random sampling of 150-250 bp reads from the reference genome. A region is called amplified or deleted if the observed read number in a window differs significantly (P<0.003) from the average of in silico-generated karyotypes. (C) Flow cell occupancy by three sequencing libraries. Two samples can be analyzed in parallel in one sequencing run on a standard MiSeq v2 flowcell when libraries are sequenced with the read numbers indicated in (A).

In order to limit the required sequencing resources to the capacities of a benchtop sequencing device, we addressed AML-relevant translocations on the level of RNA using anchored multiplex PCR10 for targeted enrichment of chimeric transcripts. RNA-based detection of common gene fusions in AML and DNA-based mutational screening are already available through predesigned commercial kits (Online Supplementary Tables S1-S4) with associated analysis software. Thus, we included numerical karyotyping into our platform by a strategy that does not require specific target enrichment. In particular, we performed low coverage whole genome sequencing (lc-WGS), which has been shown previously to enable robust detection of CNV.1211 For data analysis, we developed novel algorithms for the detection of CNV (Figure 1B) and KMT2A-PTD (CAI[N] and PTDi, respectively). Moreover, we added ITD-seek7 for the identification of FLT3-ITD to the available bioinformatics pipelines for fusion- or mutation calling. Depending on the size of the mutation panel, one or two samples can be analyzed at a time on a standard (maximum 15 ×10 reads) flowcell (Figure 1C). Operational costs per sample are comparable to the total expenses for conventional cytogenetics, fluorescence in situ hybridization (FISH) and mutation analysis. Taken together, our integrated NGS approach rapidly and economically delivers clinically meaningful insights into AML genomes, opening up the possibility to inform treatment decisions early based on molecular features and calculated cytogenetic information.

Principles of the CAI[N] algorithm and stability of in silico-generated reference karyotypes

In order to facilitate clinical interpretation, we modified the concept of “virtual” or “digital” karyotypes1413 and constructed “calculated karyotypes” from NGS data which resemble cytogenetic karyotypes. CNV in the range from cytogenetic bands to whole chromosomes are conveniently identified using a read depth approach15 and require only 5-10% genome coverage for detection with >90% sensitivity and specificity,1716 corresponding to 1-2×10 reads. CAI[N] compares read frequencies in 1 Mb fixed genomic windows to in silico-generated normal reference karyotypes and maps amplified/deleted regions to cytogenetic bands so that chromosomal gains or losses can be reported using cytogenetic notation (Figures 1B and 2A). Centromeres are not covered by our NGS karyotyping method as they include repetitive sequences that prevent unique alignment of sequencing reads.

To examine the stability of in silico reference karyotypes, we analyzed read distributions on whole chromosomes and in 1 Mb windows for random normal female and male karyotypes. Read frequencies showed very narrow variances and more reads mapped to autosomes in male karyotypes than in female ones, consistent with fewer reads mapping to the Y chromosome compared to a second X (Figure 2B). Of note, the Y chromosome appears smaller than its actual size, also due to repetitive sequences. To further investigate whether lc-WGS data resemble the results of in silico random experiments, we sequenced two libraries from healthy female donors at 1-4 ×10 reads. Read distribution patterns matched the in silico reference at all read depths examined (Figure 2C). These results confirm that lc-WGS can be accurately simulated computationally, allowing us to use random normal karyotypes as a stable reference for CNV analyses.

Figure 2.Calculated chromosome banding and in silico-generated reference karyotypes. (A) Calculated chromosome banding by CAI[N] analysis of lc-WGS data. Read distributions in genomic windows along chromosome 9 of an AML patient (AML-2, Table 1) are indicated (left: cytogenetic bands, right: 1 Mb windows. (B) Frequencies of uniquely mapped reads on whole chromosomes for in silico-generated normal karyotypes. RF: random female (N=2,819), RM: random male (N=2,605). Error bars represent the standard deviation (below visibility; <0.01%). Note that in (A) the centromere of a chromosome is not covered and in (B) the Y chromosome appears smaller than its actual size because of repetitive DNA sequences, which prevent unique alignment of sequencing reads. (C) Scalability of the CAI[N] algorithm: Four whole genome libraries from two healthy female donors were sequenced with different read numbers in multiplexed sequencing runs (right panel). Healthy F1.1-4: four runs of the same library.

Table 1.Patients’ samples and karyotypes.

Detection of chromosomal gains and losses by copy number variation karyotyping

After evaluation of CAI[N] for consistency with normal karyotypes, we determined its capacity to detect numerical aberrations. First, we examined an individual with Down syndrome (T21) and the benign meningioma cell line BEN-MEN-118 by lc-WGS and CAI[N] analysis. Both trisomy 21 in the T21 proband and loss of chromosome 22 in BEN-MEN-1 cells were identified correctly (Figure 3).

Figure 3.Detection of whole chromosome gains and losses by copy number variation karyotyping. Whole genome libraries from (A) an individual with Down syndrome (T21) and (B) the BEN-MEN-1 cell line were sequenced with low coverage and analyzed by CAI[N]. RF: random female (N=2,819), RM: random male (N=2,605). Error bars represent the standard deviation (below visibility).

Next, we investigated deletions or additions of chromosome parts in three AML patients’ samples exhibiting loss of the long arm of chromosome 5 (Table 1, Online Supplementary Figures S1-S3). CAI[N] recovered 5q deletions with different breakpoints that closely matched reference laboratory results (Figure 4A, Table 1). Moreover, a gain of chromosome 1p was detected in patient AML-1, consistent with a previously reported partial trisomy 1p (Figure 4B, Online Supplementary Figure S1, Table 1).

Figure 4.Detection of partial chromosome losses and gains by copy number variation karyotyping. Whole genome libraries from three AML patients’ samples were sequenced with low coverage and analyzed by CAI[N]. (A) Region plots for chromosome 5. (B) Region plot of chromosome 1 for patient AML-1. Read numbers in 1 Mb windows were normalized to 1 ×106 total reads. RF: random female (n=2,819), RM: random male (n=2,605). See also Online Supplementary Figures S1-S3.

Finally, to test the capability of our approach to identify chromosomal gains or losses that are not readily detected by cytogenetic banding, we performed CNV karyotyping on two AML cell lines, HL-60 and NB-4. We observed complex patterns of copy number alterations in both cell lines, including massive overrepresentation of 8q24.21 (containing the MYC locus) with loss of the remaining parts of chromosome 8 (Online Supplementary Figures S4A,B, S5 and S6, Online Supplementary Tables S5 and S6), as described previously.2619 Amplification of MYC was validated by quantitative PCR in HL-60 and NB-4 cells and in patient AML-2, in whom a copy number gain of 8q24 had not been observed by cytogenetics. Similarly, quantitative PCR analysis of three loci on chromosome 7q (ARHGEF5, PIK3CG, VKORC1L1) confirmed that this region was amplified in NB-4 cells and not lost in AML-2 (Online Supplementary Figures S2 and S4C, Table 1).

In summary, our results demonstrate that lc-WGS followed by CAI[N] analysis correctly identifies copy number changes with high resolution and allows specific genes to be linked directly to amplified or deleted regions.

Sensitivity of CAI[N] copy number variation karyotyping

To test the sensitivity of our karyotyping approach, we performed lc-WGS and CAI[N] analysis on a dilution series of BEN-MEN-1 DNA in healthy donor DNA. Moreover, we investigated samples with different blast contents which were prepared after enrichment of CD34-positive cells from the peripheral blood of patient AML-4 by magnetic bead separation.27 Loss of chromosome 22 was readily detectable in mixtures containing as little as 10% BEN-MEN-1 DNA (Figure 5). Deletion of chromosome 7q was recovered by CNV karyotyping for blast contents ≥20% with almost identical breakpoints (Online Supplementary Figure S7, Table 1). As loss of chromosome 7q was not present in all cells in the CD34-positve blast population (Table 1), the detection limit for this aberration was slightly higher than for monosomy 22, which is found in all BEN-MEN-1 cells. These findings indicate that the sensitivity of CAI[N]-CNV karyotyping is sufficient to detect highly prevalent chromosomal aberrations in AML samples with a blast count of at least 20% without prior enrichment of the blast population.

Figure 5.Sensitivity of copy number variation karyotyping. Genomic DNA from the BEN-MEN-1 cell line (monosomy 22) was diluted in healthy donor DNA (Healthy F1, Figure 2) in different ratios and subjected to lc-WGS and CAI[N] analysis. (A) Region plots for chromosome 22. The range ±3 standard deviations around the mean is indicated in pale red. (B) CNV decision plots. Read numbers in 1 Mb windows were normalized to 1×106 total reads. RF: random female (N=2,819). Color coding in (B) as in (A).

Fusion gene and DNA variant detection

Our composite assay relies on predesigned amplicon panels for the detection of fusion transcripts and DNA variants. Amplification strategies implemented in these kits10 or, respectively, specific panels, have already been extensively evaluated.287 Thus, we focused our studies on the detection of all subclass-defining translocations and all major types of clinically relevant DNA variants in adult AML. To investigate coverage of important fusion genes, we analyzed cell lines and patients’ samples harboring or lacking frequent chimeric transcripts. All expected fusions were identified in KASUMI-1,29 ME-1,30 NB-4,21 AML-5, AML-6 and CML-1, including two variants31 of BCR-ABL1 in the last sample. On the other hand, no fusions were detected in HL-6019 cells and in a patient with hypereosinophilic syndrome (HES-1), as reported by the reference laboratory (Online Supplementary Figure S8A, Online Supplementary Table S7). In a pool of the four cell lines, all fusions were recovered, but in a 1:25 dilution thereof, only the RUNX1-RUNX1T1 fusion transcript was identified. This finding underlines that RNA-based fusion detection is expression-dependent, so that the sensitivity of the assay varies for different samples and fusions.

Moreover, we exemplarily tested the TruSight Myeloid panel (Illumina) and the QIASeq™ Myeloid Neoplasms panel (Qiagen), which incorporates molecular barcodes for PCR-error correction,32 as screening tools to identify short DNA variants in AML genomes. All single nucleotide variants detected in HL-60, NB-4, ME-1, MV4-11 and SKNO-1 cells by the TruSight Myeloid panel were consistent with COSMIC33 data or confirmed by Sanger sequencing, and the QiaSeq™ panel uncovered all reported mutations in samples from two patients with AML (Online Supplementary Table S8). Sequencing a dilution series of MV4-11 DNA revealed detection limits for the two p53 mutations of 1% and 10% with the TruSight® and QiaSeq™ panels, respectively (Online Supplementary Figure S8B). Therefore, amplicon sequencing enables variant detection with analytical sensitivities that, in well-covered regions, are equivalent to those of Sanger sequencing, the reference method for clinical mutation testing.3534

Larger DNA sequence variants such as FLT3-ITD and KMT2A-PTD require special attention in NGS data analysis as they may be missed by common variant calling tools.3736 Thus, previous authors have added ITD-seek to the TruSight Myeloid analysis pipeline.7 Applying this tool to our MV4-11 dilution series, we identified a 34 bp insertion in FLT3 exon 14, which closely matched published results,38 with an analytical sensitivity of 10% (Online Supplementary Figure S9A). The FLT3-ITD was not detected in the 10% MV4-11 sample using the QiaSeq™ panel with smCounter analysis, presumably because of suboptimal coverage achieved in our sequencing runs. However, given that our work with commercial kits aimed at clarifying their principal applicability for diagnostic purposes, we did not repeat these experiments.

For the identification of KMT2A-PTD in amplicon sequencing data, we developed PTDi by adapting a tool that had been used previously with a capture-based targeted sequencing approach.36 PTDi analysis revealed amplification of exons 3-8 in patient AML-7 with a known e3e9 KMT2A-PTD (Online Supplementary Figure S9B, Online Supplementary Table S9). Thus, not only are short DNA variants detectable by amplicon sequencing, but also difficult ITD and PTD. Taken together, our results clearly confirm that combining RNA- and DNA-based amplicon panels allows all major translocations and all types of clinically relevant mutations in AML to be uncovered by NGS.

Evaluation of the comprehensive next-generation sequencing platform for the diagnosis of acute myeloid leukemia in a clinical setting

After testing the performance of all sequencing modules and bioinformatics procedures, we evaluated the clinical utility of our platform as a diagnostic tool. As our karyotype studies in cell lines clearly showed that NGS detects a higher number of numerical aberrations than chromosome banding (Online Supplementary Tables S5 and S6), we first investigated a potential need for manual review of the raw CAI[N] output in order to avoid overestimation of karyotype complexity and enable appropriate risk stratification (Table 1, Online Supplementary Tables S10 and S11). We performed lc-WGS on additional patients’ samples and reconstructed CNV karyotypes by cross comparison of CAI[N] results and known cytogenetic findings. All non-complex karyotypes, including three samples with presumably normal karyotypes in which cytogenetic analysis had failed, were identified correctly (AML-5, -7-11a/b, -13, -16, -17, -19, HES-1 / AML-14, -15, -20). In two samples that had not been characterized extensively by FISH, CNV karyotyping apparently identified marker chromosomes or detected additional aberrations (AML-2 / AML-1). Moreover, CAI[N] revealed copy number changes for five of six chromosomes involved in translocations in a highly complex karyotype (AML-3), but missed loss of chromosome 10, which had been detected in <10% of cells by interphase FISH. In four patients, for whom cytogenetics had not been performed when samples were taken, NGS recovered at least a subset of aberrant clones or a normal karyotype as reported at initial diagnosis (AML-4, -6, -12 / AML-18, respectively). Taken together, overall karyotype complexity was determined correctly in all cases and 13/13 samples without risk-defining translocations were accurately assigned to prognostic groups based on CNV karyotyping alone (Online Supplementary Table S10). Thus, we did not specifically validate discordant results between conventional and NGS karyotyping.

Next, to study patients’ samples in an unbiased manner, a group of four of the authors performed blinded analysis of CNV, fusion genes and mutations on eight additional AML samples and one acute lymphocytic leukemia sample (AML-21–28, ALL-1;39 Table 1, Online Supplementary Tables S7-S9). Two samples were excluded before unblinding because of insufficient read coverage resulting from poor DNA quality (AML-26, -27). In the remaining samples, CNV karyotyping uncovered all expected numerical changes and one additional aberration, gain of chromosome 19 in patient AML-28. Fusion analysis identified all translocations previously described in these patients. Variant analysis revealed no single nucleotide variants, insertions, deletions or ITD in this series of samples, in agreement with reference results. These findings further underscore the potential diagnostic value of our assay for the clinical management of AML.

Discussion

Here we developed and validated an integrated diagnostic platform that exclusively utilizes state-of-the-art NGS technology to obtain comprehensive clinically relevant insights into AML genomes. Our targeted approach covers all genetic features that define subclasses of AML with recurrent genetic abnormalities and/or prognostic groups as well as potentially actionable mutations92 and thus can serve as a potential alternative for diverse classical cytogenetics and molecular biology assays in certain laboratory settings. In contrast to a previously described single-run NGS assay for AML diagnosis,40 we did not include detection of copy number neutral loss of heterozygosity,4241 as its prognostic value in AML43 is not fully established.2

We examine numerical aberrations, translocations, short sequence variants, FLT3-ITD and KMT2A-PTD in a rapid, robust and reliable composite assay. Our platform uses a benchtop sequencing device and commercially available reagents and kits, thus facilitating implementation even at smaller diagnostic centers that currently cannot offer the full spectrum of molecular and cytogenetic analyses required for a complete genetic work-up of AML. NGS results differ from diagnostic reports obtained by current standard techniques in two major aspects: first, NGS karyotyping by lc-WGS and fusion transcript analysis does not reveal insights into the potential clonal heterogeneity of the disease, and second, DNA-based mutation testing yields variant allele frequencies rather than allelic ratios. While the observed frequency of cytogenetic abnormalities in a certain number of metaphases is not relevant for risk stratification, mutational burden is highly prognostically relevant for FLT3-ITD. Allelic ratios calculated from fragment analysis are not equivalent to variant allele frequencies, but based on our data presented here we cannot propose a conversion from variant allele frequencies to the established risk stratification parameter.

In the method described here, sequencing resources are most effectively reduced by fusion detection on the level of RNA using anchored multiplex PCR for target enrichment. Anchored multiplex PCR requires previous knowledge on only one fusion partner, which is targeted by a gene-specific primer included in the sequencing panel,10 so that even novel translocations involving commonly rearranged genes can be detected using a relatively low-complexity primer pool. Moreover, if a translocation does not result in a fusion transcript, but rather in transcriptional activation of a target gene, such as MECOM overexpression in AML with inv(3)(q21.3;q26.2) or t(3;3)(q21.3;q26.2),44 the underlying chromosomal rearrangement may be deduced from relative expression analyses via molecular barcode quantification. In contrast, translocation detection on the level of DNA needs to cover large intronic breakpoint regions and therefore requires higher throughput sequencing equipment or limitation of the assay to a subset of AML-relevant translocations.464540

Most importantly, our approach provides an easy to use tool for “numerical” karyotyping, that – differently from single nucleotide polymorphism-karyotyping methods40 – enables CNV analysis in a completely unbiased manner without the need for specific capture probes. Notably, the CAI[N] algorithm does not uncover absolute ploidy, but classifies gains and losses even in strongly altered hypo- or hyperdiploid cases (e.g. HL-60 and NB-4 cells).

Despite mapping to chromosome bands, CNV karyotyping by lc-WGS and CAI[N] analysis identifies chromosomal gains and losses at higher resolution than conventional cytogenetics (1 Mb versus 5-10 Mb). Subcytogenetic CNV have been observed previously by array-based comparative genomic hybridization in both complex and normal karyotype AML, including recurrent aberrations with potential prognostic impact, such as gain of 8q24.474132 Moreover, NGS karyotyping does not require short-term culture of the sample material and therefore eliminates a major technical challenge of classical cytogenetics and potential biases in clonally heterogeneous populations. For example, gain of chromosome 19 has been reported to be missed frequently by conventional banding techniques,48 as observed here in patient AML-28. Nevertheless, we did not verify this finding by an alternative detection method. Given that NGS technology is increasingly used by diagnostic laboratories, the lc-WGS strategy described here opens up the possibility of performing high-resolution numerical karyotyping of AML samples on a routine basis. On the other hand, unlike classical chromosome banding or FISH analyses, CNV karyotyping combined with targeted resequencing of chromosomal fusions will not identify balanced translocations that are not covered by the sequencing panel. These features include some abnormalities defining AML with myelodysplasia-related changes, which is not, however, exclusively a genetic diagnosis.9 Hence, larger cohorts of AML patients will have to be examined in order to develop a new risk stratification system that incorporates the gain of information obtained by lc-WGS (or array-based comparative genomic hybridization) compared to cytogenetics and potential gaps of knowledge that may emerge with a particular CNV karyotyping strategy. Future studies also need to include more extensive validation of the sensitivity of our CNV karyotyping assay to detect chromosomal gains and losses in regions that have not been specifically investigated here.

In summary, to the best of our knowledge, our work represents the fastest and most comprehensive analysis platform for diagnosing AML developed so far. Combining molecular genetics and cytogenetics in one NGS run will pave the way for differentiated management of AML patients not only in clinical trials, but also in a standard-of-care setting, as is currently emerging with midostaurin as the first targeted agent in induction therapy for patients with FLT3 alterations.49

Acknowledgments

We thank Lisa-Marie Koch, Ute Niebergall and Kathleen Stabla for excellent technical assistance and Prof. Edison T. Liu for helpful advice.

Footnotes

  • * These authors contributed equally to this work.
  • Check the online version for the most updated information on this article, online supplements, and information on authorship & disclosures: www.haematologica.org/content/104/2/277
  • FundingThis work was supported by grants from Rhön Klinikum AG (RKA n. 64 to EKMM, CB, MGK), Deutsche Forschungsgemeinschaft KFO210 (BR2232/2 to CB; Ne310/18-1 to AN), Deutsche José Carreras Leukämie-Stiftung (AH06-01 to AN, 18R/2016 to EKMM) and Stiftung PE Kempkes (06/2014 to EKMM).
  • Received May 26, 2018.
  • Accepted September 5, 2018.

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Article Information

Vol. 104 No. 2 (2019): February, 2019 : Articles
 
DOI
https://doi.org/10.3324/haematol.2018.194258
Pubmed
30190345
Pubmed Central
PMC6355503
 
Published
2019-02-01
Published By
Ferrata Storti Foundation, Pavia, Italy
Print ISSN
0390-6078
Online ISSN
1592-8721
 

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