Cosimo Cumbo

Droplet digital PCR analysis of NOTCH1 gene mutations in chronic lymphocytic leukemia.

In chronic lymphocytic leukemia (CLL), NOTCH1 gene mutations (NOTCH1mut) have been associated with adverse prognostic features but the independence of these as a prognostic factor is still controversial. In our study we validated a c.7541-7542delCT NOTCH1 mutation assay based on droplet digital PCR (ddPCR); we also analyzed the NOTCH1mut allelic burden, expressed as fractional abundance (FA), in 88 CLL patients at diagnosis to assess its prognostic role and made a longitudinal ddPCR analysis in 10 cases harboring NOTCH1mut to verify the FA variation over time. Our data revealed that with the ddPCR approach the incidence of NOTCH1mut in CLL was much higher (53.4%) than expected. However, longitudinal ddPCR analysis of CLL cases showed a statistically significant reduction of the NOTCH1mut FA detected at diagnosis after treatment (median FA 11.67 % vs 0.09 %, respectively, p = 0.01); the same difference, in terms of NOTCH1mut FA, was observed in the relapsed cases compared to the NOTCH1mut allelic fraction observed in patients in complete or partial remission (median FA 4.75% vs 0.43%, respectively, p = 0.007). Our study demonstrated a much higher incidence of NOTCH1mut in CLL than has previously been reported, and showed that the NOTCH1mut allelic burden evaluation by ddPCR might identify patients in need of a closer clinical follow-up during the “watch and wait” interval and after standard chemotherapy.

Droplet digital PCR assay for quantifying of CALR mutant allelic burden in myeloproliferative neoplasms

Dear Editor, Calreticulin (CALR) gene mutations (CALR) have recently been discovered in about 20–35 % of patients affected by essential thrombocythemia (ET) and primarymyelofibrosis (PMF) [1, 2]. Several molecular assays have been developed to detect the most frequentCALR (type 1 consisting of a 52bp deletion, and type 2 of a 5-bp insertion) [3, 4]. All these techniques are useful for identifyingCALR at the diagnosis, but they are not suitable for minimal residual disease (MRD) monitoring, since the maximum sensitivity is 1 %. The droplet digital PCR (ddPCR) technology is a third-generation PCR method that started to be used in hematological malignancies [5–7].We describe a ddPCR assay with a sensitivity of 0.01% developed for the absolute quantification of CALR type 1 and 2 mutations and analyze a cohort of 57 JAK2V617F-negative myeloproliferative neoplasm patients. ddPCR experiments were performed using the QX-200 instrument (BioRad) and specific primers and probes were designed for both type 1 and type 2 mutations (see Supplementary Files). CALR load in each sample was expressed as fractional abundance (FA, mutant allele/mutant allele + wild-type allele). The CALR allelic burden resulted heterogeneous in both ET (min.13.8 %– max. 51%) and PMF (min. 34.5%–max. 51.3%) patients.We show that the medianCALR allelic burden at diagnosis was significantly higher in PMF patients as compared to ET case (47.9 vs 43.8 %, p = 0.008) whereas no significant difference was observed between the type 1 and 2 mutations (Fig. 1a). Moreover, no relationship between the genemutation type and the CALR amount was observed within each group of ET and PMF patients. In our ET series, there were 14 (29.7 %) patients with a very low FA, <30 %; this group was not statistically different in terms of hemoglobin, white blood cells and platelet counts, age, sex, thrombosis and/or hemorrhage, and CALR type compared to those with FA >30 %. The PMF group included ten patients, too few for any type of statistical considerations. Sequential evaluations by ddPCR experiments were performed in three patients to monitor the CALR load during treatment. CALR load at diagnosis was 15.8 and 48 % in two ET patients. The former patient was treated with interferon-α (IFN-α) and after 5 years from diagnosis the FA was 7.7 %. The latter was also treated with IFN-α and after 2 years from diagnosis, the CALR load was 14.7 %. Both patients had stable disease and a well-controlled platelet count. A 44-year-old man at PMF diagnosis showed a FA of 49.7 %; 8 years later, we observed a leukemic transformation. At the time of the AML evolution, theCALR load was 0 %; this finding was also confirmed by PCR qualitative analysis. The patient underwent induction chemotherapy, achieving complete remission, then allogeneic bone marrow transplantation (ABMT) from a HLA-matched related donor. Two months later, the FA observed by ddPCR analysis was 0.01 %; 7 months after, the ABMT and AML relapsed and at this time, the CALR load was 13.5 % (Fig. 1b, c). Although the importance of the CALR allelic burden determination has not yet been defined at the disease onset, the utility of and need for a sensitive method, like our ddPCR assay, are unquestionable for the purposes of MRD monitoring [8–10]. Electronic supplementary material The online version of this article (doi:10.1007/s00277-016-2739-2) contains supplementary material, which is available to authorized users.

Overexpression of the LSAMP and TUSC7 genes in acute myeloid leukemia following microdeletion/duplication of chromosome 3

The 3q13.31 microdeletion syndrome is characterized by developmental delay, postnatal growth above the mean, characteristic facial features, and abnormal male genitalia. Moreover, a frequent deletion in the 3q13.31 chromosome region has been identified in patients who are affected by osteosarcomas. Among the genes located within the deleted region, the involvement of the limbic system-associated membrane protein gene (LSAMP), together with a non-coding RNA tumor suppressor candidate 7 gene (TUSC7), has been suggested. We describe the case of an adult acute myeloid leukemia (AML) patient with a novel chromosomal rearrangement characterized by a 3q13.31 microdeletion and an extra copy of the 3q13.31-q29 chromosomal region translocated to the long arm of the Y chromosome. This karyotypic aberration seems to cause LSAMP and TUSC7 gene expression dysregulation. In conclusion, we report the first case of LSAMP and TUSC7 gene overexpression, possibly due to a position effect in an AML patient bearing a 3q13.31 cryptic deletion.

Droplet Digital PCR Is a Reliable Tool for Monitoring Minimal Residual Disease in Acute Promyelocytic Leukemia

Nested RT-PCR (nPCR) and real-time quantitative PCR (qPCR) are well-established methods for monitoring minimal residual disease (MRD) in acute promyelocytic leukemia (APL). Despite their remarkable sensitivity and specificity, both methods have inherent limitations, such as qualitative MRD evaluation and relative quantification. Herein, we used droplet digital PCR (ddPCR) to monitor MRD in 21 APL patients and compared its performance with nPCR and qPCR. After assessing the limit of detection (LOD) for each technique on serial dilutions of PML-RARA bcr1 and bcr3 transcripts, a total of 48 follow-up samples were analyzed and the results compared. ddPCR showed good linearity and efficiency and reached an LOD comparable or even superior to nPCR and qPCR. When tested on primary samples, ddPCR exhibited a sensitivity and specificity of ≥95% and ≥91% for bcr1 and bcr3 transcripts and displayed a significant concordance with both techniques, particularly with nPCR. The peculiar advantage of ddPCR-based monitoring of MRD is represented by absolute quantification, which provides crucial information for the management of patients whose MRD fluctuates under the LOD of qPCR and is detectable, but not quantifiable, by nPCR. Our findings highlight ddPCR as a reliable complementary approach to monitor MRD in APL, and suggest its advantageous application, particularly for the molecular follow-up of patients at high risk of relapse.

5'RUNX1-3'USP42 chimeric gene in acute myeloid leukemia can occur through an insertion mechanism rather than translocation and may be mediated by genomic segmental duplications

BackgroundThe runt-related transcription factor 1 (RUNX1) gene is a transcription factor that acts as a master regulator of hematopoiesis and represents one of the most frequent targets of chromosomal rearrangements in human leukemias. The t(7;21)(p22;q22) rearrangement generating a 5‘RUNX1-3’USP42 fusion transcript has been reported in two cases of pediatric acute myeloid leukemia (AML) and further in eight adult cases of myeloid neoplasms. We describe the first case of adult AML with a 5‘RUNX1-3’USP42 fusion gene generated by an insertion event instead of chromosomal translocation.MethodsConventional and molecular cytogenetic analyses allowed the precise characterization of the chromosomal rearrangement and breakpoints identification. Gene expression analysis was performed by quantitative real-time PCR experiments, whereas bioinformatic studies were carried out for revealing structural genomic characteristics of breakpoint regions.ResultsWe identified an adult AML case bearing a ins(21;7)(q22;p15p22) generating a 5‘RUNX1-3’USP42 fusion gene on der(21) chromosome and causing USP42 gene over-expression. Bioinformatic analysis of the genomic regions involved in ins(21;7)/t(7;21) showed the presence of interchromosomal segmental duplications (SDs) next to the USP42 and RUNX1 genes, that may underlie a non-allelic homologous recombination between chromosome 7 and 21 in AML.ConclusionsWe report the first case of a 5‘RUNX1-3’USP42 chimeric gene generated by a chromosomal cryptic insertion in an adult AML patient. Our data revealed that there may be a pivotal role for SDs in this very rare but recurrent chromosomal rearrangement.

Genomic BCR-ABL1 breakpoint characterization by a multi-strategy approach for “personalized monitoring” of residual disease in chronic myeloid leukemia patients

For monitoring minimal residual disease (MRD) in chronic myeloid leukemia (CML) the most recommended method is quantitative RT-PCR (RT-qPCR) for measuring BCR-ABL1 transcripts. Several studies reported that a DNA-based assay enhances the sensitivity of detection of the BCR-ABL1 genomic rearrangement, even if its characterization results difficult. We developed a DNA-based method for detecting and quantifying residual BCR-ABL1 positive leukemic stem cells in CML patients. We propose two alternative approaches: the first one is a fluorescence in situ hybridization (FISH)-based step followed by Sanger sequencing; the second one employs MinION, a single molecule sequencer based on nanopore technology. Finally, after defining the BCR-ABL1 genomic junction, we performed the target CML patient–specific quantification, using droplet digital PCR (ddPCR). FISH and MinION steps, respectively, together with ddPCR analysis, greatly reduce the complexity that has impeded the use of “personalized monitoring” of CML in clinical practice. Our report suggests a feasible pipeline, in terms of costs and reproducibility, aimed at characterizing and quantifying the genomic BCR-ABL1 rearrangement during MRD monitoring in CML patients.

Mutational analysis in BCR-ABL1 positive leukemia by deep sequencing based on nanopore MinION technology

We report a third-generation sequencing assay on nanopore technology (MinION) for detecting BCR-ABL1 KD mutations and compare the results to a Sanger sequencing(SS)-based test in 24 Philadelphia-positive (Ph+) leukemia cases. Our data indicates that MinION is markedly superior to SS in terms of sensitivity, costs and timesaving, and has the added advantage of determining the clonal configuration of multiple mutations. We demonstrate that MinION is suitable for employment in the hematology laboratory for detecting BCR-ABL1 KD mutation in Ph+ leukemias.

Myelodysplastic syndrome with 5q deletion following IgM monoclonal gammopathy, showing gene mutation MYD88 L265P

Patients affected by monoclonal gammopathy of undetermined significance (MGUS) very rarely develop a myelodysplastic syndrome (MDS). However, it was also demonstrated that MGUS patients had a significantly increased risk of developing MDS compared to the general population. We report a case of 5q-syndrome following a MGUS IgMk with mutation of MYD88 L256P. To our knowledge, this is the first case of del(5q) MDS following MGUS IgMk with the MYD88 L256P mutation in which there is coexistence of the markers of the two clonal diseases, but as an expression of distinct pathological features.

ADAMTS2 gene dysregulation in T/myeloid mixed phenotype acute leukemia

BackgroundMixed phenotype acute leukemias (MPAL) include acute leukemias with blasts that express antigens of more than one lineage, with no clear evidence of myeloid or lymphoid lineage differentiation. T/myeloid (T/My) MPAL not otherwise specified (NOS) is a rare leukemia that expresses both T and myeloid antigens, accounting for less than 1% of all leukemias but 89% of T/My MPAL. From a molecular point of view, very limited data are available on T/My MPAL NOS.Case presentationIn this report we describe a T/My MPAL NOS case with a complex rearrangement involving chromosomes 5 and 14, resulting in overexpression of the ADAM metallopeptidase with thrombospondin type 1 motif, 2 (ADAMTS2) gene due to its juxtaposition to the T cell receptor delta (TRD) gene segment.ConclusionDetailed molecular cytogenetic characterization of the complex rearrangement in the reported T/My MPAL case allowed us to observe ADAMTS2 gene overexpression, identifying a molecular marker that may be useful for monitoring minimal residual disease. To our knowledge, this is the first evidence of gene dysregulation due to a chromosomal rearrangement in T/My MPAL NOS.

Design and MinION testing of a nanopore targeted gene sequencing panel for chronic lymphocytic leukemia

We report a customized gene panel assay based on multiplex long-PCR followed by third generation sequencing on nanopore technology (MinION), designed to analyze five frequently mutated genes in chronic lymphocytic leukemia (CLL): TP53, NOTCH1, BIRC3, SF3B1 and MYD88. For this purpose, 12 patients were selected according to specific cytogenetic and molecular features significantly associated with their mutational status. In addition, simultaneous analysis of the targets genes was performed by molecular assays or Sanger Sequencing. Data analysis included mapping to the GRCh37 human reference genome, variant calling and annotation, and average sequencing depth/error rate analysis. The sequencing depth resulted on average higher for smaller amplicons, and the final breadth of coverage of the panel was 94.1%. The error rate was about 6% and 2% for insertions/deletions and single nucleotide variants, respectively. Our gene panel allows analysis of the prognostically relevant genes in CLL, with two PCRs per patient. This strategy offers an easy and affordable workflow, although further advances are required to improve the accuracy of the technology and its use in the clinical field. Nevertheless, the rapid and constant development of nanopore technology, in terms of chemistry advances, more accurate basecallers and analysis software, offers promise for a wide use of MinION in the future.