European recommendations and quality assurance for cytogenomic analysis of haematological neoplasms.

Cytogenomic investigations of haematological neoplasms, including chromosome banding analysis, fluorescence in situ hybridisation (FISH) and microarray analyses have become increasingly important in the clinical management of patients with haematological neoplasms. The widespread implementation of these techniques in genetic diagnostics has highlighted the need for guidance on the essential criteria to follow when providing cytogenomic testing, regardless of choice of methodology. These recommendations provide an updated, practical and easily available document that will assist laboratories in the choice of testing and methodology enabling them to operate within acceptable standards and maintain a quality service.

Number of RUNX1 mutations, wild-type allele loss and additional mutations impact on prognosis in adult RUNX1-mutated AML.

RUNX1-mutated acute myeloid leukemia (AML) show a distinct pattern of genetic abnormalities and an adverse prognosis. We analyzed the impact of multiple RUNX1 mutations and RUNX1 wild-type (WT) loss in 467 AML with RUNX1 mutations (mut): (1) RUNX1 WT loss (n=53), (2) >1 RUNX1mut (n=94) and (3) 1 RUNX1mut (n=323). In 1 RUNX1mut, +8 was most frequent, whereas in WT loss +13 was the most abundant trisomy (+8: 66% vs 31%, P=0.022; +13: 15% vs 62%, P<0.001). Analyses of 28 genes in 163 selected cases revealed SRSF2 (39%), ASXL1 (36%), DNMT3A (19%), IDH2 (17%) and SF3B1 (17%) as most frequently mutated genes. RUNX1 WT loss showed a higher frequency of ASXL1mut compared with the other cases (50% vs 29%, P=0.009). Median overall survival (OS) in the total cohort was 14 months. WT loss (OS: 5 months) and >1 RUNX1mut (14 months) showed an adverse impact on prognosis compared with 1 RUNX1mut (22 months; P=0.002 and 0.048, respectively). Mutations in ASXL1 and ⩾2 additional mutations correlated with shorter OS (10 vs 18 months, P=0.028; 12 vs 20 months, P=0.017). Thus, the number of RUNX1mut, RUNX1 WT loss and the number and type of additional mutations is biologically and clinically relevant.

Assessment of imatinib as first-line treatment of chronic myeloid leukemia: 10-year survival results of the randomized CML study IV and impact of non-CML determinants.

Chronic myeloid leukemia (CML)-study IV was designed to explore whether treatment with imatinib (IM) at 400 mg/day (n=400) could be optimized by doubling the dose (n=420), adding interferon (IFN) (n=430) or cytarabine (n=158) or using IM after IFN-failure (n=128). From July 2002 to March 2012, 1551 newly diagnosed patients in chronic phase were randomized into a 5-arm study. The study was powered to detect a survival difference of 5% at 5 years. After a median observation time of 9.5 years, 10-year overall survival was 82%, 10-year progression-free survival was 80% and 10-year relative survival was 92%. Survival between IM400 mg and any experimental arm was not different. In a multivariate analysis, risk group, major-route chromosomal aberrations, comorbidities, smoking and treatment center (academic vs other) influenced survival significantly, but not any form of treatment optimization. Patients reaching the molecular response milestones at 3, 6 and 12 months had a significant survival advantage. For responders, monotherapy with IM400 mg provides a close to normal life expectancy independent of the time to response. Survival is more determined by patients' and disease factors than by initial treatment selection. Although improvements are also needed for refractory disease, more life-time can currently be gained by carefully addressing non-CML determinants of survival.

Molecular characterization of EZH2 mutant patients with myelodysplastic/myeloproliferative neoplasms.

Mutations in the epigenetic regulator gene EZH2 are frequently observed in patients with myelodysplastic/myeloproliferative neoplasms (MDS/MPN; 10-13%) and are associated with a poor outcome. To gain more insight into EZH2 pathology, we sought to genetically characterize a cohort of 41 EZH2-mutated MDS/MPN patients using targeted deep next-generation sequencing (NGS), colony-forming progenitor assays and transcriptome analysis. Stable short hairpin RNA (shRNA)-mediated downregulation of EZH2 was performed in MDS-derived F-36P, MOLM-13 and OCI-M2 cells to study EZH2-specific changes. Targeted NGS revealed a complex pattern of mutations with a total of 190 individual mutations. EZH2 mutations frequently co-occur with TET2 (58%), RUNX1 (40%) and ASXL1 (34%) mutations. Colony assays indicated EZH2 mutations to be mostly early events in leukemogenesis and showed a complex mutational hierarchy. Gene expression data revealed a number of differently expressed genes between EZH2 wild-type and mutant patients including known EZH2 targets. Comparison of patient transcriptome to EZH2-downregulated cell line data revealed several genes as novel EZH2 targets, showing opposite as well as unidirectional regulation between cell lines and patients. Some genes, such as CXXC5, ETS1 and VAV3 have previously been implied to have a role in leukemogenesis. Their precise role in MDS/MPN needs to be further investigated.

Subtype-specific patterns of molecular mutations in acute myeloid leukemia.

Acute myeloid leukemia (AML) can be grouped into morphologically or genetically defined subtypes. Today, the AML phenotype-genotype associations, that is, FAB/WHO (French-American-British/World Health Organization) definitions and recurrent molecular mutations, are not fully understood. Therefore, we evaluated the impact of molecular mutations on the AML differentiation stage by molecular profiling of 4373 adult de novo AML patients in 7 cytomorphological subtypes. We investigated mutations in 20 genes, including myeloid transcription factors (CEBPA, RUNX1), tumor suppressors (TP53, WT1), DNA modifiers (DNMT3A, IDH1/2, TET2), chromatin modifiers (ASXL1, MLL), signal transduction genes (FLT3, KRAS, NRAS) and NPM1. The most frequently mutated genes per cytomorphological subtype were RUNX1 in M0 (43%), NPM1 in M1 (42%), DNMT3A in M2 (26%), NPM1 in M4 (57%), M5a (49%) and M5b (70%) and TP53 in M6 (36%). Although some gene mutations were frequent in several cytomorphological subtypes, a series of associations of co-occurring mutations with distinct phenotypes were identified for molecularly defined subcohorts. FLT3, NPM1 and WT1 mutations were associated with an immature phenotype in myeloblastic AML, whereas other combinations involving ASXL1, RUNX1, MLL-PTD, CEBPA or KRAS were more frequent in myeloblastic AML with maturation. Within the NPM1 mutated subcohort, ASXL1 mutations were significantly associated with a monoblastic differentiation and DNMT3A mutations with a monocytic phenotype.

The impact of TP53 mutations and TP53 deletions on survival varies between AML, ALL, MDS and CLL: an analysis of 3307 cases.

Alterations in TP53 have been described in many cancer types including hematological neoplasms. We aimed at comparing TP53 mutations (mut) and deletions (del) in a large cohort of patients with hematological malignancies (n=3307), including AML (n=858), MDS (n=943), ALL (n=358), CLL (n=1148). Overall, alterations in TP53 were detected in 332/3307 cases (10%). The highest frequency was observed in ALL (total: 19%; mut+del: 6%; mut only: 8%; del only: 5%) and AML (total: 13%; mut+del: 5%; mut only: 7%; del only: 1%), whereas TP53 alterations occurred less frequently in CLL (total: 8%) and MDS (total: 7%). TP53 mutations were significantly more frequent in patients ⩾60 vs <60 years in AML (9% vs 2%, P<0.001) and ALL (12% vs 6%, P<0.001). TP53mut+del had a significant negative impact on overall survival in all entities, whereas differences were observed regarding TP53mut only or TP53del only: TP53mut only impacted survival in AML (36 vs 9 months, P<0.001) and MDS (65 vs 19 months, P<0.001), TP53del only in CLL (not reached vs 64 months, P=0.008) and MDS (65 vs 24 months, P=0.011). As substantial differences between the entities are observed regarding correlation to age and survival, we suggest evaluation of both TP53 deletion and mutation status.

Genetic characterization of MYD88-mutated lymphoplasmacytic lymphoma in comparison with MYD88-mutated chronic lymphocytic leukemia.

MYD88 (myeloid differentiation primary response 88) is mutated in the majority of Waldenström macroglobulinemia/lymphoplasmacytic lymphoma (LPL); but also, albeit less frequently, in other B-cell malignancies, including chronic lymphocytic leukemia (CLL). This suggests MYD88 as a central regulator of pathogenesis, but requests a broader approach to define diagnostically relevant genetic profiles for LPL and CLL. We identified the L265P hotspot mutation in 86% (n=67/78) of our LPL and 2% (n=12/767) of our CLL cohort. Importantly, in CLL (n=5), but also in LPL (n=4) other MYD88 mutations were identified. MYD88-mutated LPL was characterized by CXCR4 mutations (25%) and del(6q) (19%), whereas both aberrations were absent in the MYD88-unmutated LPL cases. MYD88-mutated CLL formed a prognostically favorable subset with a high frequency of del(13q), mutated IGHV status and no adverse aberrations (del(11q), del(17p), TP53 mutations). MYD88-mutated CLL differed from LPL with respect to cytogenetic aberrations and the absence of CXCR4 mutations. In both entities, based on mutation load evaluation, MYD88 mutations were found to be present in the stem clone in each case, whereas CXCR4 (LPL) and SF3B1 (CLL) mutations also occurred in subclones only.

The role of the RAS pathway in iAMP21-ALL.

Intrachromosomal amplification of chromosome 21 (iAMP21) identifies a high-risk subtype of acute lymphoblastic leukaemia (ALL), requiring intensive treatment to reduce their relapse risk. Improved understanding of the genomic landscape of iAMP21-ALL will ascertain whether these patients may benefit from targeted therapy. We performed whole-exome sequencing of eight iAMP21-ALL samples. The mutation rate was dramatically disparate between cases (average 24.9, range 5-51) and a large number of novel variants were identified, including frequent mutation of the RAS/MEK/ERK pathway. Targeted sequencing of a larger cohort revealed that 60% (25/42) of diagnostic iAMP21-ALL samples harboured 42 distinct RAS pathway mutations. High sequencing coverage demonstrated heterogeneity in the form of multiple RAS pathway mutations within the same sample and diverse variant allele frequencies (VAFs) (2-52%), similar to other subtypes of ALL. Constitutive RAS pathway activation was observed in iAMP21 samples that harboured mutations in the predominant clone (⩾35% VAF). Viable iAMP21 cells from primary xenografts showed reduced viability in response to the MEK1/2 inhibitor, selumetinib, in vitro. As clonal (⩾35% VAF) mutations were detected in 26% (11/42) of iAMP21-ALL, this evidence of response to RAS pathway inhibitors may offer the possibility to introduce targeted therapy to improve therapeutic efficacy in these high-risk patients.

Newly acquired kiwi fruit allergy after bone marrow transplantation from a kiwi-allergic donor.

BACKGROUND: The phenomenon of allergy transfer from an allergic donor to a non-allergic recipient via hematopoietic cell transplantation has been described by several reports. However, it could not yet been conclusively shown that allergic reaction of the recipient is elicited by the donor's cells. OBJECTIVES: In the case of a 46-year-old male patient who - for the first time in his life - had two episodes of oral allergic syndrome upon kiwi consumption after having received myeloablative hematopoietic stem cell transplantation (HCT) from his kiwi-allergic sister, we aimed to clarify the origin of allergen reactive cells in the donor. We not only intended to demonstrate if allergy was transferred by HCT but also to present an experimental workup for the analysis of allergy transfer by HCT. METHODS: Allergic sensitization to kiwi in recipient and donor was proven by ImmunoCAP. Furthermore, origin of peripheral blood mononuclear cells (PBMCs) was analyzed by chromosomal fluorescence in situ hybridization (FISH). To confirm allergic reaction and activation of hematopoietic cells by customized kiwi extract, we performed basophil activation test from whole blood as well as T cell proliferation assays from purified PBMCs of both recipient and donor. RESULTS: Basophil activation upon kiwi extract was demonstrated in both recipient and donor. Besides, we showed proliferation of CD4(+) T cells after incubation with kiwi extract. FISH analysis proved that hematopoietic cells of the male recipient completely originated from the female donor. CONCLUSION: Exemplified in this patient, we show for the first time that allergy transfer is mediated by the donor's cells. Moreover, our experimental approach using customized kiwi extract to prove contribution of kiwi-specific T and B cells in both kiwi-allergic recipient and donor could serve as a model approach for future studies.