Acute myeloid leukaemia (FAB AML-M4Eo) with cryptic insertion of cbfb resulting in cbfb-Myh11 fusion.

Inv(16)(p13q22) and t(16;16)(p13;q22) are cytogenetic hallmarks of acute myelomonoblastic leukaemia, most of them associated with abnormal bone marrow eosinophils [acute myeloid leukaemia French-American-British classification M4 with eosinophilia (FAB AML-M4Eo)] and a relatively favourable clinical course. They generate a 5'CBFB-3'MYH11 fusion gene. However, in a few cases, although RT-PCR identified a CBFB-MYH11 transcript, normal karyotype and/or fluorescent in situ hybridization (FISH) analyses using commercially available probes are found. We identified a 32-year-old woman with AML-M4Eo and normal karyotype and FISH results. Using two libraries of Bacterial Artificial Chromosome clones on 16p13 and 16q22, FISH analyses identified an insertion of 16q22 material in band 16p13, generating a CBFB-MYH11 type A transcript. Although very rare, insertions should be searched for in patients with discordant cytological and cytogenetic features because of the therapeutic consequences. Copyright © 2015 John Wiley & Sons, Ltd.

Breakpoint heterogeneity in (2;3)(p15-23;q26) translocations involving EVI1 in myeloid hemopathies.

Several chromosomal rearrangements involving band 3q26 are known to induce EVI1 overexpression. They include inv(3)(q21q26), t(3;3)(q21;q26), t(3;21)(q26;q22) and t(3;12)(q26;p13). Translocations involving the short arm of chromosome 2 and 3q26 have been reported in more than 50 patients with myeloid disorders. However, although the breakpoints on 2p are scattered over a long segment, their distribution had only been analyzed in 9 patients. We performed fluorescent in situ hybridization with a library of BAC (Bacterial Artificial Chromosome) clones in 4 patients with t(2;3)(p15-23;q26). Our results combined with those of the 9 previously reported patients showed scattering of the breakpoints in 2 regions. A 1.08Mb region in band 2p21 encompassing the MTA3, ZFP36L2 and THADA genes was documented in 5 patients. A second region of 1.83Mb in band 2p16.1 was identified in 8 patients. Four patients showed clustering around the BCL11A gene and the remaining 4 around a long intergenic non-coding RNA, FLJ30838. These regions are characterized by the presence of regulatory sequences (CpG islands and promoters) that could be instrumental in EVI1 overexpression.

3q26/EVI1 rearrangements in myeloid hemopathies: a cytogenetic review.

The EVI1 gene, located in chromosomal band 3q26, is a transcription factor that has stem cell-specific expression pattern and is essential for the regulation of self-renewal of hematopoietic stem cells. It is now recognized as one of the dominant oncogenes associated with myeloid leukemia. EVI1 overexpression is associated with minimal to no response to chemotherapy and poor clinical outcome. Several chromosomal rearrangements involving band 3q26 are known to induce EVI1 overexpression. They are mainly found in acute myeloid leukemia and blastic phase of Philadelphia chromosome-positive chronic myeloid leukemia, more rarely in myelodysplastic syndromes. They include inv(3)(q21q26), t(3;3)(q21;q26), t(3;21)(q26;q22), t(3;12)(q26;p13) and t(2;3)(p15-23;q26). However, many other chromosomal rearrangements involving 3q26/EVI1 have been identified. The precise molecular event has not been elucidated in the majority of these chromosomal abnormalities and most gene partners remain unknown.

Hox gene dysregulation in acute myeloid leukemia.

In humans, class I homeobox genes (HOX genes) are distributed in four clusters. Upstream regulators include transcriptional activators and members of the CDX family of transcription factors. HOX genes encode proteins and need cofactor interactions, to increase their specificity and selectivity. HOX genes contribute to the organization and regulation of hematopoiesis by controlling the balance between proliferation and differentiation. Changes in HOX gene expression can be associated with chromosomal rearrangements generating fusion genes, such as those involving MLL and NUP98, or molecular defects, such as mutations in NPM1 and CEBPA for example. Several miRNAs are involved in the control of HOX gene expression and their expression correlates with HOX gene dysregulation. HOX genes dysregulation is a dominant mechanism of leukemic transformation. A better knowledge of their target genes and the mechanisms by which their dysregulated expression contributes to leukemogenesis could lead to the development of new drugs.

Subtelomeric monosomy 11q and trisomy 16q in siblings and an unrelated child: molecular characterization of two der(11)t(11;16).

We report here three children with a der(11)t(11;16), two sibs (patients 1 and 2) having inherited a recombinant chromosome from a maternal t(11;16)(q24.3;q23.2) and a third unrelated child with a de novo der(11)t(11;16)(q25;q22.1), leading to partial monosomy 11q and trisomy 16q. Fluorescent in situ hybridization (FISH) using bacterial artificial chromosome (BAC) clones and array-CGH were performed to determine the breakpoints involved in the familial and the de novo rearrangements. The partial 11 monosomy extended from 11q24.3 to 11qter and measured 6.17-6.21 Mb in Patients 1 and 2 while the size of the partial 11q25->qter monosomy was estimated at 1.97-2.11 Mb for Patient 3. The partial 16 trisomy extended from 16q23.2 to 16qter and measured 8.93-8.95 Mb in Patients 1 and 2 while the size of the partial 16q22.1->qter trisomy was 20.82 Mb for Patient 3. Intraventricular hemorrhage and transitional thrombocytopenia were found in both sibs but not in the third patient. The FLI1 gene, which is the most relevant gene for thrombocytopenia in Jacobsen syndrome, was neither deleted in family A nor in Patient 3. We suggest that a positional effect could affect the FLI1 expression for these two sibs. Deafness of our three patients confirmed the association of this anomaly to 11q monosomy and tended to confirm the hypothetic role of DFNB20 in Jacobsen syndrome hearing loss. Both sibs shared most of the features commonly observed in Jacobsen syndrome, but not the third patient. This confirmed that terminal 11q trisomy spanning 1 to 1.97-2.11 Mb is not associated with a typical Jacobsen syndrome.

Using bacterial artificial chromosomes in leukemia research: the experience at the university cytogenetics laboratory in Brest, France.

The development of the bacterial artificial chromosome (BAC) system was driven in part by the human genome project in order to construct genomic DNA libraries and physical maps for genomic sequencing. The availability of BAC clones has become a valuable tool for identifying cancer genes. We report here our experience in identifying genes located at breakpoints of chromosomal rearrangements and in defining the size and boundaries of deletions in hematological diseases. The methodology used in our laboratory consists of a three-step approach using conventional cytogenetics followed by FISH with commercial probes, then BAC clones. One limitation to the BAC system is that it can only accommodate inserts of up to 300 kb. As a consequence, analyzing the extent of deletions requires a large amount of material. Array comparative genomic hybridization (array-CGH) using a BAC/PAC system can be an alternative. However, this technique has limitations also, and it cannot be used to identify candidate genes at breakpoints of chromosomal rearrangements such as translocations, insertions, and inversions.

RUNX1 translocations and fusion genes in malignant hemopathies.

The RUNX1 gene, located in chromosome 21q22, is crucial for the establishment of definitive hematopoiesis and the generation of hematopoietic stem cells in the embryo. It contains a 'Runt homology domain' as well as transcription activation and inhibition domains. RUNX1 can act as activator or repressor of target gene expression depending upon the large number of transcription factors, coactivators and corepressors that interact with it. Translocations involving chromosomal band 21q22 are regularly identified in leukemia patients. Most of them are associated with a rearrangement of RUNX1. Indeed, at present, 55 partner chromosomal bands have been described but the partner gene has solely been identified in 21 translocations at the molecular level. All the translocations that retain Runt homology domains but remove the transcription activation domain have a leukemogenic effect by acting as dominant negative inhibitors of wild-type RUNX1 in transcription activation.

Complex and cryptic chromosomal rearrangements involving the MLL gene in acute leukemia: a study of 7 patients and review of the literature.

Chromosomal rearrangements involving the MLL gene have been associated with many different types of hematological malignancies. Most of them are easily recognized by conventional cytogenetics. However, in some cases, complex, unusual or cryptic rearrangements make the MLL involvement difficult or impossible to be detected by conventional cytogenetics. Fluorescent in situ hybridization with a panel of probes coupled with long distance inverse-PCR was used to identify chromosomal rearrangements involving the MLL gene. Seven unusual chromosomal rearrangements were identified, including two complex translocations, three insertions of material of chromosome 11 in another chromosome and one insertion of chromosome material into the MLL gene. Conventional cytogenetics showed three patients to have a deletion of 11q; one had an unexpected t(6;11)(q27;q23) whereas the other two patients had also an insertion of MLL material in another chromosome. Concurrent 3' deletion in the MLL rearrangement was observed in two patients. We recommend a systematic approach to be used in all cases of acute leukemia starting with FISH analyses using a commercially available MLL split signal probe. Should an abnormality be discovered, the analysis has to be completed by further molecular cytogenetic and genomic PCR methods in order to unravel the recombination mechanism.

Difficult diagnosis and management of an heterokaryotypic monochorionic twin pregnancy with discordant fetal sex and 45,X/47,XYY karyotypes.

We report twins for whom ultrasound examinations revealed a Turner syndrome in the female fetus and a normal male fetus. A selective pregnancy termination was decided on the female fetus with hydrops. The death of both twins called in question the chorionic diagnosis. Amniotic fluid cytogenetic analysis revealed a 45,X karyotype in the female twin and a 47,XYY karyotype in the male twin. Molecular cytogenetic analysis on genital and renal cells showed different levels of 45,X/47,XYY mosaicism in both twins; molecular analysis on the amniocytes showed monozygosity. Monozygotic twins with discordant sex are very rare. This study showed the difficult diagnosis and management of a monochorionic twin pregnancy with discordant fetal sex.

Familial interstitial deletion of the short arm of chromosome 4 (p15.33-p16.3) characterized by molecular cytogenetic analysis.

This 15-month boy was expressed at the cytogenetic laboratory because of psychomotor development delay. He was tall and had plagiocephaly, micrognathia, high nasal bridge, anteverted nostrils and pectus excavatum. A 46,XY,del(4)(p16.1p16.3) karyotype was found using high-resolution R-banding technique. FISH studies using the LSI Wolf-Hirschhorn dual color 4p16.3 and the TelVysion 4p probes showed no deletion. Using BACs, the distal breakpoint was located in 4p16.3, between RP11-165K4 and RP11-717M10 and the proximal breakpoint in 4p15.33, between RP11-74M11 and RP11-1J7; therefore, approximately 7.96 Mb of the short arm were deleted. The maternal karyotype showed the same deletion, but in a mosaic status. Two distinct phenotypes have been recognized on the basis of the chromosomal bands involved in 4p deletion: the Wolf-Hirschhorn syndrome (WHS) and a proximal 4p deletion syndrome (4p15.2-p15.32). Our observation confirms that the basic WHS phenotype maps distally to this region.

Chromosome 20 deletions in myelodysplastic syndromes and Philadelphia-chromosome-negative myeloproliferative disorders: characterization by molecular cytogenetics of commonly deleted and retained regions.

Deletion of the long arm of chromosome 20 is a recurrent abnormality observed in myelodysplastic syndromes (MDS) and in Philadelphia-chromosome-negative myeloproliferative disorders (MPD). Our objective was to characterize the deletion size among 38 MDS and MPD patients using fluorescence in situ hybridization (FISH) with bacterial artificial chromosome (BAC) probes and to define commonly deleted and retained regions on chromosome 20. Patients were distributed in three groups according to the World Health Organization classification: MDS (22 patients), MPD (12 patients) and myelodysplastic/myeloproliferative diseases (four patients). FISH with centromeric, subtelomeric, and unique sequence probes was performed to characterize the deletion whereas its size was delineated using BAC clones. All 38 deletions were found to be interstitial. A commonly deleted region was identified for each of the three groups; it varied from 6.62 to 10.4 Mb and showed considerable overlapping. Two commonly retained regions (CRR), also showing overlapping, were identified in all three groups, one in the centromeric region, the other in the telomeric region. The deletion size is highly variable, with no apparent recurrent breakpoint. The deletion may result in the loss of one or several tumor suppressor genes but the target genes remain unknown. Loss of genes plays an important part in the myeloid leukemic process associated with del(20q). However, genes located in the retained chromosomal regions may also play a role in the oncogenetic mechanisms.

Translocation (10;17)(p15;q21) is a recurrent anomaly in acute myeloblastic leukemia.

We report here two cases of patients with acute myeloblastic leukemia, type M1 (FAB classification), associated with a t(10;17)(p15;q21). Fluorescence in situ hybridization with the LSI PML/RARA dual-color probe showed the breakpoint to be distal to the RARA locus. Four other patients with this translocation have been reported, three of them having acute undifferentiated or poorly differentiated leukemia.

Evaluation of chromosome 5 aberrations in complex karyotypes of patients with myeloid disorders reveals their contribution to dicentric and tricentric chromosomes, resulting in the loss of critical 5q regions.

Dicentric chromosomes have often been observed in complex karyotypes in previously reported studies of therapy-related myelodysplastic syndromes (MDS) and acute myeloid leukemia (AML). Fluorescence in situ hybridization (FISH) has now made the characterization of these rearrangements much easier. Dicentric and tricentric chromosomes were identified in 21 patients (9 MDS and 12 AML) among the 133 consecutive MDS/AML patients (17%) who had a structural or numerical aberration of chromosome 5 using conventional cytogenetic analysis. One third (7/21) of the patients had received alkylating drugs for a previously diagnosed cancer or chronic myeloproliferative disease. Loss of 5q material was identified in all 21 patients. One copy of the EGR1 (5q31) or the CSF1R (5q33 approximately q34) genes was lost in 20 of the 21 patients. Dicentric and tricentric chromosomes involving chromosome 5 are frequently observed in complex karyotypes among patients with de novo or therapy-related MDS/AML. They lead to deletions of various parts of the long arm of chromosome 5.

Deletion size characterization of der(9) deletions in Philadelphia-positive chronic myeloid leukemia.

About 95% of the CML patients with chronic myeloid leukemia (CML) have a Philadelphia chromosome resulting from a reciprocal translocation between bands 9q34 and 22q11.2 that juxtaposes the 3' region of the ABL gene to the 5' region of BCR. Over the past few years, submicroscopic deletions due to the loss of sequences proximal to chromosome 9 breakpoint or distal to chromosome 22 breakpoint have been found using fluorescence in situ hybridization (FISH). Among 150 CML bone marrow samples analyzed by molecular cytogenetics in our laboratory, 11 had a der(9) deletion detectable by FISH (deletion of the 5'ABL region and 3'BCR region in 10 samples and deletion of the 5'ABL region solely in 1 sample). To delineate the size of the deletions, FISH mapping was performed using 22 bacterial artificial chromosomes (BACs), 11 on either side of the breakpoints, the mean distance between BACs being 0.5 Mb. The deletion size of the 5'ABL region on the der(9) extended from 2 to 5 Mb, the minimal deletion size being localized between BACs RP11-101E3 and RP11-83J21. In two patients, the deletion size of the 3'BCR region was about 500 kb (between RP11-80O7 and RP11-681C06). The poor prognosis associated with these deletions was postulated by several workers to be explained by haploinsufficiency of a tumor suppressor gene. However, in our cases, the hypothetical deletion of one or more tumor suppressor genes is not sufficient to explain the poor response to interferon therapy, but the good response to imatinib treatment. We think that there could be one or more genes coding for interferon receptors or for proteins acting directly or indirectly with these receptors in the deleted regions.

Chromosome 1 abnormalities in multiple myeloma.

Multiple myeloma (MM) is a malignancy of the terminally-differentiated B cells and accounts for 10% of all hematological malignancies. Chromosome 1 aberrations are frequently described, the short arm being preferentially involved in deletions and the long arm in gains. The abnormalities were identified in the bone marrow of 37 MM patients by conventional cytogenetics. Fluorescence in situ hybridization (FISH) was used to confirm the presence of the abnormalities and to better characterize them. Chromosome 1 abnormalities were grouped into 4 categories: balanced translocations, deletions, amplifications and jumping translocations (JT). Breakpoints involved in balanced translocations were randomly distributed. The smallest region of overlap for deletions was 1p11 --> 1p21 (present in 27% of the patients) and for gains 1q31 --> 1qter (present in 54% of the patients). The whole long arm was found to be the donor segment for the majority of patients with JT, the most frequent recipients being chromosomes 16 and 19. Our results share some similarities with those obtained for 143 published patients studied by FISH. Band 1p21 was found to be frequently deleted, leading to the assumption that a 1p deletion could lead to hemizygosity of at least 1 tumor suppressor gene. Two regions of 1q showed preferential gains: q12 to q22 and q31 to q42; these amplifications could induce the overexpression of 1 or more oncogenes. In conclusion, our results confirm that chromosome 1 abnormalities play an important role in the pathogenesis of multiple myeloma.

Immunoglobulin gene translocations in chronic lymphocytic leukemia: A report of 35 patients and review of the literature.

Chronic lymphocytic leukemia (CLL) represents the most common hematological malignancy in Western countries, with a highly heterogeneous clinical course and prognosis. Translocations involving the immunoglobulin (IG) genes are regularly identified. From 2000 to 2014, we identified an IG gene translocation in 18 of the 396 patients investigated at diagnosis (4.6%) and in 17 of the 275 analyzed during follow-up (6.2%). A total of 4 patients in whom the IG translocation was identified at follow-up did not carry the translocation at diagnosis. The IG heavy locus (IGH) was involved in 27 translocations (77.1%), the IG κ locus (IGK) in 1 (2.9%) and the IG λ locus (IGL) in 7 (20.0%). The chromosome band partners of the IG translocations were 18q21 in 16 cases (45.7%), 11q13 and 19q13 in 4 cases each (11.4% each), 8q24 in 3 cases (8.6%), 7q21 in 2 cases (5.7%), whereas 6 other bands were involved once (2.9% each). At present, 35 partner chromosomal bands have been described, but the partner gene has solely been identified in 10 translocations. CLL associated with IG gene translocations is characterized by atypical cell morphology, including plasmacytoid characteristics, and the propensity of being enriched in prolymphocytes. The IG heavy chain variable region (IGHV) mutational status varies between translocations, those with unmutated IGHV presumably involving cells at an earlier stage of B-cell lineage. All the partner genes thus far identified are involved in the control of cell proliferation and/or apoptosis. The translocated partner gene becomes transcriptionally deregulated as a consequence of its transposition into the IG locus. With the exception of t(14;18)(q32;q21) and its variants, prognosis appears to be poor for the other translocations. Therefore, searching for translocations involving not only IGH, but also IGL and IGK, by banding and molecular cytogenetics is required. Furthermore, it is important to identify the partner gene to ensure the patients receive the optimal treatment.

Cryptic 5' MLL gene insertion in an X-chromosome in acute myeloblastic leukemia.

Band 11q23 is known to be involved in translocations and insertions with a variety of partner chromosomes. They lead to MLL rearrangement, resulting in fusion with numerous genes. We report here on a 43-year-old man presenting with asthenia and pancytopenia who was diagnosed with acute myeloblastic leukemia FAB-M5. Conventional cytogenetic techniques showed a del(11)(q21). Using a specific probe for fluorescent in situ hybridization, the MLL gene was found to be disrupted, with the 5' region being inserted into the X-chromosome (around bands q24 approximately q25), as confirmed by whole X-chromosome painting. The accumulating data on acute myeloblastic leukemia demonstrate that the 5'-MLL insertion in an X-chromosome is a rare but recurrent abnormality associated with leukemia, not only in infants, but also in adults.