Detailed molecular cytogenetic characterisation of the myeloid cell line U937 reveals the fate of homologous chromosomes and shows that centromere capture is a feature of genome instability.

BACKGROUND: The U937 cell line is widely employed as a research tool. It has a complex karyotype. A PICALM-MLLT10 fusion gene formed by the recurrent t(10;11) translocation is present, and the myeloid common deleted region at 20q12 has been lost from its near-triploid karyotype. We carried out a detailed investigation of U937 genome reorganisation including the chromosome 20 rearrangements and other complex rearrangements. RESULTS: SNP array, G-banding and Multicolour FISH identified chromosome segments resulting from unbalanced and balanced rearrangements. The organisation of the abnormal chromosomes containing these segments was then reconstructed with the strategic use of targeted metaphase FISH. This provided more accurate karyotype information for the evolving karyotype. Rearrangements involving the homologues of a chromosome pair could be differentiated in most instances. Centromere capture was demonstrated in an abnormal chromosome containing parts of chromosomes 16 and 20 which were stabilised by joining to a short section of chromosome containing an 11 centromere. This adds to the growing number of examples of centromere capture, which to date have a high incidence in complex karyotypes where the centromeres of the rearranged chromosomes are identified. There were two normal copies of one chromosome 20 homologue, and complex rearrangement of the other homologue including loss of the 20q12 common deleted region. This confirmed the previously reported loss of heterozygosity of this region in U937, and defined the rearrangements giving rise to this loss. CONCLUSIONS: Centromere capture, stabilising chromosomes pieced together from multiple segments, may be a common feature of complex karyotypes. However, it has only recently been recognised, as this requires deliberate identification of the centromeres of abnormal chromosomes. The approach presented here is invaluable for studying complex reorganised genomes such as those produced by chromothripsis, and provides a more complete picture than can be obtained by microarray, karyotyping or FISH studies alone. One major advantage of SNP arrays for this process is that the two homologues can usually be distinguished when there is more than one rearrangement of a chromosome pair. Tracking the fate of each homologue and of highly repetitive DNA regions such as centromeres helps build a picture of genome evolution. Centromere- and telomere-containing elements are important to deducing chromosome structure. This study confirms and highlights ongoing evolution in cultured cell lines.

BCL-XL inhibition by BH3-mimetic drugs induces apoptosis in models of Epstein-Barr virus-associated T/NK-cell lymphoma.

Epstein-Barr virus (EBV)-associated T- and natural killer (NK)-cell malignancies, such as extranodal NK-/T-cell lymphoma (ENKTL), exhibit high chemoresistance and, accordingly, such patients have a poor prognosis. The rare nature of such cancers and nonmalignant T/NK lymphoproliferative disorders, such as chronic active EBV (CAEBV), has limited our understanding of the pathogenesis of these diseases. Here, we characterize a panel of ENKTL- and CAEBV-derived cell lines that had been established from human tumors to be used as preclinical models of these diseases. These cell lines were interleukin-2 dependent and found to carry EBV in a latency II gene-expression pattern. All cell lines demonstrated resistance to cell death induction by DNA damage-inducing agents, the current standard of care for patients with these malignancies. This resistance was not correlated with the function of the multidrug efflux pump, P-glycoprotein. However, apoptotic cell death could be consistently induced following treatment with A-1331852, a BH3-mimetic drug that specifically inhibits the prosurvival protein BCL-XL. A-1331852-induced apoptosis was most efficacious when prosurvival MCL-1 was additionally targeted, either by BH3-mimetics or genetic deletion. Xenograft models established from the ENKTL cell line SNK6 provided evidence that A-1331852 treatment could be therapeutically beneficial in vivo. The data here suggest that therapeutic targeting of BCL-XL would be effective for patients with EBV-driven T/NK proliferative diseases, however, MCL-1 could be a potential resistance factor.

Hemopoietic Cell Kinase amplification with Protein Tyrosine Phosphatase Receptor T depletion leads to polycythemia, aberrant marrow erythoid maturation, and splenomegaly.

Deletion of long arm of chromosome 20 [del(20q)] is the second most frequent recurrent chromosomal abnormality in hematological malignancies. It is detected in 10% of myeloproliferative neoplasms, 4-5% of myelodysplastic syndromes, and 1-2% of acute myeloid leukaemia. Recurrent, non-random occurrence of del(20q) indicates that it is a pathogenic driver in myeloid malignancies. Genetic mapping of patient samples has identified two regions of interest on 20q - the "Common Deleted Region" (CDR) and "Common Retained Region" (CRR), which was often amplified. We proposed that the CDR contained tumor suppressor gene(s) (TSG) and the CRR harbored oncogene(s); loss of a TSG together with over-expression of an oncogene favored development of myeloid malignancies. Protein Tyrosine Phosphatase Receptor T (PTPRT) and Hemopoietic cell kinase (HCK) were identified to be the likely candidate TSG and oncogene respectively. Retroviral transduction of HCK into PTPRT-null murine LKS+ stem and progenitor cells resulted in hyperproliferation in colony forming assays and hyperphosphorylation of intracellular STAT3. Furthermore, over half of the murine recipients of these transduced cells developed erythroid hyperplasia, polycythemia and splenomegaly at 12 months, although no leukemic phenotype was observed. The findings suggested that HCK amplification coupled with PTPRT loss in del(20q) leads to development of a myeloproliferative phenotype.

MACROD2 Haploinsufficiency Impairs Catalytic Activity of PARP1 and Promotes Chromosome Instability and Growth of Intestinal Tumors.

ADP-ribosylation is an important posttranslational protein modification that regulates diverse biological processes, controlled by dedicated transferases and hydrolases. Here, we show that frequent deletions (∼30%) of the MACROD2 mono-ADP-ribosylhydrolase locus in human colorectal cancer cause impaired PARP1 transferase activity in a gene dosage-dependent manner. MACROD2 haploinsufficiency alters DNA repair and sensitivity to DNA damage and results in chromosome instability. Heterozygous and homozygous depletion of Macrod2 enhances intestinal tumorigenesis in ApcMin/+ mice and the growth of human colorectal cancer xenografts. MACROD2 deletion in sporadic colorectal cancer is associated with the extent of chromosome instability, independent of clinical parameters and other known genetic drivers. We conclude that MACROD2 acts as a haploinsufficient tumor suppressor, with loss of function promoting chromosome instability, thereby driving cancer evolution.Significance: Chromosome instability (CIN) is a hallmark of cancer. We identify MACROD2 deletion as a cause of CIN in human colorectal cancer. MACROD2 loss causes repression of PARP1 activity, impairing DNA repair. MACROD2 haploinsufficiency promotes CIN and intestinal tumor growth. Our results reveal MACROD2 as a major caretaker tumor suppressor gene. Cancer Discov; 8(8); 988-1005. ©2018 AACR.See related commentary by Jin and Burkard, p. 921This article is highlighted in the In This Issue feature, p. 899.

Analysis of Chromothripsis by Combined FISH and Microarray Analysis.

Fluorescence in situ hybridization (FISH) to metaphase chromosomes, in conjunction with SNP array, array CGH, or whole genome sequencing, can help determine the organization of abnormal genomes after chromothripsis and other types of complex genome rearrangement. DNA microarrays can identify the changes in copy number, but they do not give information on the organization of the abnormal chromosomes, balanced rearrangements, or abnormalities of the centromeres and other regions comprised of highly repetitive DNA. Many of these details can be determined by the strategic use of metaphase FISH. FISH is a single-cell technique, so it can identify low-frequency chromosome abnormalities, and it can determine which chromosome abnormalities occur in the same or different clonal populations. These are important considerations in cancer. Metaphase chromosomes are intact, so information about abnormalities of the chromosome homologues is preserved. Here we describe strategies for working out the organization of highly rearranged genomes by combining SNP array data with various metaphase FISH methods. This approach can also be used to address some of the uncertainties arising from whole genome or mate-pair sequencing data.

Active centromere and chromosome identification in fixed cell lines.

BACKGROUND: The centromere plays a crucial role in ensuring the fidelity of chromosome segregation during cell divisions. However, in cancer and constitutional disorders, the presence of more than one active centromere on a chromosome may be a contributing factor to chromosome instability and could also have predictive value in disease progression, making the detection of properly functioning centromeres important. Thus far, antibodies that are widely used for functional centromere detection mainly work on freshly harvested cells whereas most cytogenetic samples are stored long-term in methanol-acetic acid fixative. Hence, we aimed to identify antibodies that would recognise active centromere antigens on methanol-acetic acid fixed cells. RESULTS: A panel of active centromere protein antibodies was tested and we found that a rabbit monoclonal antibody against human CENP-C recognises the active centromeres of cells fixed in methanol-acetic acid. We then tested and compared combinations of established methods namely centromere fluorescence in situ hybridisation (cenFISH), centromere protein immunofluorescence (CENP-IF) and multicolour FISH (mFISH), and showed the usefulness of CENP-IF together with cenFISH followed by mFISH (CENP-IF-cenFISH-mFISH) with the aforementioned anti-CENP-C antibody. We further demonstrated the utility of our method in two cancer cell lines with high proportion of centromere defects namely neocentromere and functional dicentric. CONCLUSIONS: We propose the incorporation of the CENP-IF-cenFISH-mFISH method using a commercially available rabbit monoclonal anti-CENP-C into established methods such as dicentric chromosome assay (DCA), prenatal karyotype screening in addition to constitutional and cancer karyotyping. This method will provide a more accurate assessment of centromere abnormality status in chromosome instability disorders.

The Dicentric Chromosome dic(20;22) Is a Recurrent Abnormality in Myelodysplastic Syndromes and Is a Product of Telomere Fusion.

We describe a recurrent dicentric chromosome formed by telomere fusion between chromosome 20 and chromosome 22 in 4 cases of myelodysplastic syndromes (MDS) or acute myeloid leukaemia (AML). In particular, the presence of residual telomere sequences at the site of translocation in 3 of the 4 cases makes a compelling case for telomere fusion. This is the first description of a recurrent telomere fusion event in any malignant condition. The 20q subtelomeric region was retained in all 4 examples despite deletion of the 20q12 region closer to the centromere. The original dicentric chromosome in all 4 cases contained nucleolus organiser region material from the short arm of chromosome 22 and had also undergone secondary rearrangements that produced amplification of the common gained region on 20q. We propose that the sequence of events producing this chromosome abnormality is: degradation of the telomeres, formation of an unstable dicentric chromosome by 20q and 22p telomere fusion, breakage-fusion-bridge cycles causing copy number aberration between the centromeres, selection of cells with 20q12 deletion, and further selection of cells with 20q11.2 gain. The last 2 steps are driver events responsible for the abnormal chromosomes found in the malignant cells. Finding recurrent patterns in the complex genome reorganisation events that characterise poor-prognosis, complex-karyotype AML and MDS will help us understand the mechanisms and oncogenic driver mutations in these poorly understood malignancies.

Src family kinases and their role in hematological malignancies.

The Src family protein tyrosine kinases (SFKs) are non-receptor intracellular kinases that have important roles in both hematopoiesis and leukemogenesis. The derangement of their expression or activation has been demonstrated to contribute to hematological malignancies. This review first examines the mechanisms of SFK overexpression and hyperactivation, emphasizing the dysregulation of the upstream modulators. Subsequently, the role of SFK up-regulation in the initiation, progression and therapy resistance of many hematological malignancies is also analyzed. The presented evidence endeavors to highlight the influence of SFK up-regulation on an extensive number of hematological malignancies and the need to consider them as candidates in targeted anticancer therapy.

Chromothripsis under the microscope: a cytogenetic perspective of two cases of AML with catastrophic chromosome rearrangement.

Chromothripsis is a recently described phenomenon identified in cancer cells that produces catastrophic chromosome reorganization of one or a small number of chromosomes. It has been proposed that the multiple breakage events occur at a single point in time. Here we introduce the term anachromosome to describe an abnormal chromosome produced by chromothripsis. We report two cases of acute myeloid leukemia matching the description of chromothripsis that illustrate different aspects of this phenomenon from a cytogenetic perspective. Fluorescence in situ hybridization (FISH) analyses, including multicolor FISH and FISH for repeat elements that are not present on microarrays and that are resistant to sequencing, helped interpret the rearrangements but did not reveal their level of complexity. The anachromosomes conformed to the normal constraints of chromosome structure by including segments that provide two telomeres and a centromere. In patient samples, there are mixtures of cells with and without deletions. The deletion B allele frequencies for heterozygous loci in a mixture of cells with and without the deletions create a distinctive array pattern that is consistent with all the deletions in the anachromosomes having occurred concurrently. This evidence supporting the single-event hypothesis for chromothripsis has not previously been highlighted, to our knowledge. In the context of exploring mechanisms for chromosome shattering, we discuss a possible connection between chromosome pulverization and fragile sites. Understanding chromothripsis in the context of chromosome biology will help us identify its causes and consequences.

Genome organization and the role of centromeres in evolution of the erythroleukaemia cell line HEL.

BACKGROUND AND OBJECTIVES: The human erythroleukaemia (HEL) cell line has a highly rearranged genome. We matched whole chromosome analysis with cytogenomic microarray data to build a detailed description of these rearrangements. METHODOLOGY: We used a combination of single nucleotide polymorphism array and multiple fluorescence in situ hybridization approaches, and compared our array data with publicly available data for different sublines of HEL. B allele frequencies revealed the fate of each homologue for most chromosomes. RESULTS: At least two instances of the breakage-fusion-bridge cycle appear to have facilitated amplification of oncogenes and deletion of tumour suppressor genes. Because our study included centromere identification, we found that some abnormal chromosomes had centromeres that did not match the identity of the rest of the chromosome. CONCLUSIONS AND IMPLICATIONS: This study highlights the variety of complementary methods required to understand remodelling of the genome in cancer and uncover some of the mechanisms involved. We present evidence of centromere capture as a means of preserving broken chromosome segments. Testing for another highly repetitive DNA region, the nucleolus organizer region, helped identify the steps involved in chromosome 9 copy number aberrations. Increased use of techniques for identifying centromeres and other repetitive DNA regions will add to our understanding of genome remodelling and evolution. The pattern of chromosome 20 aberration in HEL supports an association of 20q11.21 amplification with erythroleukaemia (acute myeloid leukaemia subtype M6) in the context of 20q12 deletion. The differences between the karyotypes in different HEL sublines highlight the constantly evolving genomes of cultured cell lines.

CGH and SNP array using DNA extracted from fixed cytogenetic preparations and long-term refrigerated bone marrow specimens.

BACKGROUND: The analysis of nucleic acids is limited by the availability of archival specimens and the quality and amount of the extracted material. Archived cytogenetic preparations are stored in many laboratories and are a potential source of total genomic DNA for array karyotyping and other applications. Array CGH using DNA from fixed cytogenetic preparations has been described, but it is not known whether it can be used for SNP arrays. Diagnostic bone marrow specimens taken during the assessment of hematological malignancies are also a potential source of DNA, but it is generally assumed that DNA must be extracted, or the specimen frozen, within a day or two of collection, to obtain DNA suitable for further analysis. We have assessed DNA extracted from these materials for both SNP array and array CGH. RESULTS: We show that both SNP array and array CGH can be performed on genomic DNA extracted from cytogenetic specimens stored in Carnoy's fixative, and from bone marrow which has been stored unfrozen, at 4°C, for at least 36 days. We describe a procedure for extracting a usable concentration of total genomic DNA from cytogenetic suspensions of low cellularity. CONCLUSIONS: The ability to use these archival specimens for DNA-based analysis increases the potential for retrospective genetic analysis of clinical specimens. Fixed cytogenetic preparations and long-term refrigerated bone marrow both provide DNA suitable for array karyotyping, and may be suitable for a wider range of analytical procedures.

A cryptic deletion in 5q31.2 provides further evidence for a minimally deleted region in myelodysplastic syndromes.

Recurrent deletions of 5q in myeloid malignancies encompass two separate regions: deletion of 5q33, which is associated with the 5q− syndrome and haploinsufficiency of RPS14, and deletion of a more proximal locus at 5q31. We present a case with a cryptic 1.3 Mb deletion in 5q31.2 identified by array comparative genomic hybridization that places the proximal boundary of the deletion proximal and close to the candidate EGR1 gene. The patient was diagnosed initially with a myelodysplastic syndrome, with a del(20)(q11.2q13.3) as the sole abnormality identified by karyotyping. The patient progressed to acute myeloid leukemia with no change to the G-banded karyotype. The 1.3 Mb deletion on the long arm of one chromosome 5 was confirmed to have been present both at presentation with myelodysplastic syndrome and at transformation. This is an interesting case because there are few array studies identifying cryptic 5q deletions, and the study of these small deletions helps to refine the common deleted region. This case, together with previously published studies, suggests that the proximal boundary of the common deleted region may lie within the KDM3B gene.

Unbalanced translocations of 20q in AML and MDS often involve interstitial rather than terminal deletions of 20q.

Dicentric chromosomes can occur in myelodysplastic syndromes and acute myeloid leukemia. As these unbalanced rearrangements often combine two recurrent deletions, they could be an efficient mechanism for the loss of two tumor suppressor genes in a single step. We report here that dicentric chromosomes involving chromosome 20 with loss of the 20q12 putative tumor suppressor gene are often the result of more complex rearrangements, with the 20q12 region being lost by an interstitial deletion independent of the site of translocation. We found interstitial deletions of 20q in two thirds of the two-way translocations tested. This points to a more complex mechanism of translocation involving at least three breakpoints and two separate events, and raises questions about the order of these events and the significance of these abnormalities.

The use of M-FISH and M-BAND to define chromosome abnormalities.

Multicolour fluorescence in situ hybridisation (M-FISH) and multicolour banding (M-BAND) are advanced chromosome painting techniques combining multiple chromosome- or region-specific paints in one step. M-FISH identifies all chromosomes or chromosome arms at once, whereas M-BAND identifies the different regions of a single chromosome. The use of either or both can improve the accuracy of karyotyping and help identify cryptic chromosome rearrangements. These probes are prepared by pooling multiple chromosome- or chromosome region-specific DNA libraries, each labelled with a unique combination of fluorochromes. Commercial probes are available, avoiding the need for probe preparation. In the protocol described here, a commercial probe is used. Well-spread metaphases are prepared according to standard techniques, followed by alkaline denaturation and application of the denatured probe. After an incubation period, the slides are washed. A fluorescence microscope with filter sets specific to the fluorescent labels is used for analysis, together with specialised image analysis software. The software interprets the combination of fluorochromes to identify each chromosome and produce a false colour image specific for each chromosome or region. The single colour galleries - which show the hybridisation patterns of the individual fluorochromes - are useful to help interpret and confirm the false colour images produced by the software, including ambiguous signals.

The role of dicentric chromosome formation and secondary centromere deletion in the evolution of myeloid malignancy.

Dicentric chromosomes have been identified as instigators of the genome instability associated with cancer, but this instability is often resolved by one of a number of different secondary events. These include centromere inactivation, inversion, and intercentromeric deletion. Deletion or excision of one of the centromeres may be a significant occurrence in myeloid malignancy and other malignancies but has not previously been widely recognized, and our reports are the first describing centromere deletion in cancer cells. We review what is known about dicentric chromosomes and the mechanisms by which they can undergo stabilization in both constitutional and cancer genomes. The failure to identify centromere deletion in cancer cells until recently can be partly explained by the standard approaches to routine diagnostic cancer genome analysis, which do not identify centromeres in the context of chromosome organization. This hitherto hidden group of primary dicentric, secondary monocentric chromosomes, together with other unrecognized dicentric chromosomes, points to a greater role for dicentric chromosomes in cancer initiation and progression than is generally acknowledged. We present a model that predicts and explains a significant role for dicentric chromosomes in the formation of unbalanced translocations in malignancy.

The paradox of 20q11.21 amplification in a subset of cases of myeloid malignancy with chromosome 20 deletion.

Deletion of the long arm of one chromosome 20 (del(20q)) is a well-recognized abnormality in acute myeloid leukemia (AML) and myelodysplastic syndromes (MDS) and is presumed to cause loss of a tumor suppressor gene at 20q12. In a previously published series of MDS and AML cases, which had lost this region via unbalanced translocation, around 40% of cases were shown to have additional copies of the chromosome 20 abnormalities, with resulting gain or amplification of the retained parts of chromosome 20, most often 20q11.2. We have used FISH and array comparative genomic hybridization, to define further the retained and amplified regions. We now report targeted amplification of 20q11.21 in four of the 22 cases selected for further study and in one new case. The shortest amplified region of 250 kb in a series of five patients with three to ten copies of the 20q11.21 region contained the complete HCK, TM9SF4, PLAGL2, and POFUT1 genes. By RT-PCR we have shown that there is correlation between amplification and increased expression of these four genes in most cases. Localized and high level amplification of the common 250 kb region is evidence for activation of an oncogene in this region in these MDS and AML cases. Cases with 20q11.21 amplification tended to have a high proportion of erythroblasts in the marrow, with two cases diagnosed as erythroleukemia (AML-M6). Chromosome sub-band 20q11.21 amplification may therefore prove to be a marker of a specific subset of AML/MDS with a significant erythroid component.

A FISH comparison of variant derivatives of the recurrent dic(17;20) of myelodysplastic syndromes and acute myeloid leukemia: Obligatory retention of genes on 17p and 20q may explain the formation of dicentric chromosomes.

The dic(17;20) is a recurrent unbalanced translocation occurring rarely in myelodysplastic syndromes and acute myeloid leukemia. We have studied eleven cases with the dic(17;20) or a more complex derivative, all of which showed deletion of 17p and 20q material. The tumor suppressor gene TP53 was not always lost, supporting a more distal gene as the target of these 17p deletions. All derivatives could be interpreted as having initially been formed as a dicentric chromosome, those with a larger amount of material between the centromeres having undergone further rearrangement to stabilize the chromosome while retaining proximal 17p and proximal 20q material. We propose that critical sequences on both 17p and 20q proximal to the sites of deletion must be retained during the critical 17p and 20q deletions. This would explain the excess of dicentric chromosomes resulting from 17;20 translocation, and the apparent stabilization of the unstable derivatives by further rearrangements which preserve 17p and 20q material.

A comparison of two contrasting recurrent isochromosomes 20 found in myelodysplastic syndromes suggests that retention of proximal 20q is a significant factor in myeloid malignancies.

We compare two different isochromosomes of chromosome 20 in myelodysplastic syndromes (MDS): an isochromosome of the short arm of chromosome 20, idic(20)(q11), and an isochromosome of the long arm of a deleted chromosome 20, ider(20)(q10)del(20)(q11.2). The isochromosomes are of contrasting morphology, because opposite arms are duplicated, but they both show loss of the critical region at 20q12, as well as retention and duplication of the centromere and proximal long arm (20q11). We speculate that a region of proximal 20q is preferentially retained during deletions of the critical region in MDS and acute myeloid leukemia.