Genomic profile of chronic myelogenous leukemia: Imbalances associated with disease progression.

The expression of the chimeric BCR/ABL1 fusion gene resulting from t(9;22)(q34;q11) in chronic myelogenous leukemia (CML) is necessary for malignant transformation, but not sufficient to maintain disease progression. The appearance of various chromosomal and molecular alterations in the accelerated and terminal phase of CML is well documented, but evidence for causal relationship is largely lacking. We carried out a genome wide screening at a resolution of 1 Mb of 54 samples at different stages of CML together with 12 CML cell lines and found that disease progression is accompanied by a spectrum of recurrent genome imbalances. Among the most frequent are losses at 1p36, 5q21, 9p21, and 9q34 and gains at 1q, 8q24, 9q34, 16p, and 22q11, all of which were located with higher precision within the genome than previously possible. These genome imbalances are unique to CML cases with clinically manifested or suspected accelerated/blast stage alike, but not seen in chronic phase samples. Previously unrecognized cryptic imbalances occurring within the Ph-chromosome were also detected, although further scrutiny is required to pin-point gene involvement and seek association with disease features. Importantly, some of these imbalances were seen in the CD34(+) cells but not in the whole BM samples of patients in accelerated phase. Taken together, these findings highlight the potential of screening CD34(+) cells for genome wide imbalances associated with disease progression. Finally, the numerous single copy number variations recorded, many unique to this cohort of patients, raise the possible association of genome polymorphism and CML.

Application of growth factor stimulants improves cytogenetic analysis of chronic myeloproliferative disorder patients without alteration to cell lineage or clonality.

Conventional cytogenetic methods rely on culturing bone marrow aspirates to obtain suitable and sufficient mitotic figures for G-banded analysis. Samples from patients with chronic myeloproliferative disorders (CMPD) often have increased failure rates due to reduced growth and poor morphology, all of which hamper the conventional karyotyping investigation. The application of growth factor (GF) stimulants to bone marrow aspirates has been shown to yield significant increases in both the quality and quantity of bone marrow metaphases obtained in 53 CPMD patient samples. All cultures were stimulated using the conditioned supernatant from the human bladder carcinoma cell line 5637, which contains IL-3, IL-6, and G-CSF. Results were assessed qualitatively on G-banded preparations and quantitatively by mitotic index (MI = % dividing cells). To assess whether the application of GF stimulants leads to clonal selection, culture samples from 15 patients were analyzed by fluorescence in situ hybridization, which supported the theory that clonal selection remains unaltered in GF-stimulated cultures. In addition to this immunophenotyping of cells, we demonstrated the lineage of cells propagated under these conditions. Cell markers were chosen to characterize B-lymphoid, T-lymphoid, myeloid, and primitive cell types. Results indicated that T cells were maintained in culture and B-lymphoid markers remained negative. In the myeloid subset, there was an overall reduction in the pan-myeloid markers. We believe this represents the loss of terminally differentiated cells (e.g., neutrophils) in culture. Overall, the study clearly demonstrates that the application of GF stimulants does not alter clonality or cell lineage propagated in these samples and is therefore suitable for application in diagnostic cytogenetic laboratories.

Myeloproliferative disorders.

The myeloproliferative disorders (MPDs) are a group of pre-leukaemic disorders characterized by proliferation of one or more lineages of the myelo-erythroid series. Unlike the Philadelphia chromosome in chronic myeloid leukaemia, there is no pathognomonic chromosomal abnormality associated with the MPDs. Chromosomal abnormalities are seen in 30-40% of patients with polycythaemia vera (PV) and idiopathic myelofibrosis (IMF) and seem to indicate a poor prognosis. On the other hand, chromosomal abnormalities are rare in essential thrombocythaemia. Consistent acquired changes seen at diagnosis include deletion of the long arm of chromosome 20, del(13q), trisomy 8 and 9 and duplication of parts of 1q. Furthermore del(20q), trisomy 8 and dupl(lq) all arise in multipotent progenitor cells. Molecular mapping of 20q deletions and, to some extent, 13q deletions has identified a number of candidate target genes, although no mutations have yet been found. Finally, translocations associated with the rare 8p11 myeloproliferative syndrome and other atypical myeloproliferative disorders have permitted the identification of a number of novel fusion proteins involving fibroblast growth factor receptor-1.

Deletions of the derivative chromosome 9 occur at the time of the Philadelphia translocation and provide a powerful and independent prognostic indicator in chronic myeloid leukemia.

Chronic myeloid leukemia (CML) is characterized by formation of the BCR-ABL fusion gene, usually as a consequence of the Philadelphia (Ph) translocation between chromosomes 9 and 22. Large deletions on the derivative chromosome 9 have recently been reported, but it was unclear whether deletions arose during disease progression or at the time of the Ph translocation. Fluorescence in situ hybridization (FISH) analysis was used to assess the deletion status of 253 patients with CML. The strength of deletion status as a prognostic indicator was then compared to the Sokal and Hasford scoring systems. The frequency of deletions was similar at diagnosis and after disease progression but was significantly increased in patients with variant Ph translocations. In patients with a deletion, all Ph(+) metaphases carried the deletion. The median survival of patients with and without deletions was 38 months and 88 months, respectively (P =.0001). By contrast the survival difference between Sokal or Hasford high-risk and non-high-risk patients was of only borderline significance (P =.057 and P =.034). The results indicate that deletions occur at the time of the Ph translocation. An apparently simple reciprocal translocation may therefore result in considerable genetic heterogeneity ab initio, a concept that is likely to apply to other malignancies associated with translocations. Deletion status is also a powerful and independent prognostic factor for patients with CML. The prognostic significance of deletion status should now be studied prospectively and, if confirmed, should be incorporated into management decisions and the analysis of clinical trials.

Variant Philadelphia translocations in chronic myeloid leukaemia can mimic typical blast crisis chromosome abnormalities or classic t(9;22): a report of two cases.

A range of fluorescent in situ hybridization techniques have been used to reveal hidden variant Philadelphia translocations in two cases of Ph-positive chronic-phase chronic myeloid leukaemia. In one patient, a highly complex variant Ph translocation affecting four chromosomes had resulted in the formation of structures with the appearance of i(17q) and +8. Misinterpretation of these karyotypes has direct clinical relevance. Our findings illustrate that even established cytogenetic abnormalities may contain cryptic abnormalities beyond the resolution of conventional cytogenetic methods.

Screening for specific chromosome involvement in hematological malignancies using a set of seven chromosome painting probes. An alternative approach for chromosome analysis using standard FISH instrumentation.

We report the application of multi-color fluorescence in situ hydribidization (FISH) for bone marrow metaphase cell analysis of hematological malignancies using a sub-set of the human karyotype for chromosome painting. A combination of chromosome probes labeled with three haptens enabled the construction of a "painting probe" which detects seven different chromosomes. The probe was used to screen three chronic myeloid leukemia (CML) derived cell lines and ten CML patient bone marrow samples for aberrations, additional to the Ph rearrangement, that are associated with the onset of blast crisis of CML. This approach was shown to identify karyotype changes commonly seen by conventional karyotyping, and in addition revealed chromosome changes unresolved or undetected by conventional cytogenetic analysis. The seven-color painting probe provides a useful, fast, and reliable complementary tool for chromosome analysis, especially in cases with poor chromosome morphology. This is a simple approach, since the probes can be displayed in a standard red/green/blue format accessible to standard fluorescence microscopes and image-processing software. The proposed approach using panels of locus-specific probes as well as chromosome paints will be useful in all diagnostic routine environments where analysis is directed towards screening for genetic rearrangements and/or specific patterns of chromosome involvement with diagnostic/prognostic value.

Chromosome 20 deletions in myeloid malignancies: reduction of the common deleted region, generation of a PAC/BAC contig and identification of candidate genes. UK Cancer Cytogenetics Group (UKCCG).

Deletion of the long arm of chromosome 20 represents the most common chromosomal abnormality associated with the myeloproliferative disorders (MPDs) and is also found in other myeloid malignancies including myelodysplastic syndromes (MDS) and acute myeloid leukaemia (AML). Previous studies have identified a common deleted region (CDR) spanning approximately 8 Mb. We have now used G-banding, FISH or microsatellite PCR to analyse 113 patients with a 20q deletion associated with a myeloid malignancy. Our results define a new MPD CDR of 2.7 Mb, an MDS/AML CDR of 2.6 Mb and a combined 'myeloid' CDR of 1.7 Mb. We have also constructed the most detailed physical map of this region to date--a bacterial clone map spanning 5 Mb of the chromosome which contains 456 bacterial clones and 202 DNA markers. Fifty-one expressed sequences were localized within this contig of which 37 lie within the MPD CDR and 20 within the MDS/AML CDR. Of the 16 expressed sequences (six genes and 10 unique ESTs) within the 'myeloid' CDR, five were expressed in both normal bone marrow and purified CD34 positive cells. These data identify a set of genes which are both positional and expression candidates for the target gene(s) on 20q.

Cytogenetics of the chronic myeloid leukemia-derived cell line K562: karyotype clarification by multicolor fluorescence in situ hybridization, comparative genomic hybridization, and locus-specific fluorescence in situ hybridization.

The transformation of chronic myeloid leukemia (CML) from a chronic phase to an acute phase is frequently accompanied by additional chromosome changes. Extensive chromosome G-banded studies have revealed the secondary changes are nonrandom and frequently include trisomy 8, isochromosome 17q, trisomy 19, or an extra copy of the Philadelphia chromosome. In addition to these secondary chromosome changes, complex structural rearrangements often occur to form marker structures that remain unidentified by conventional G-banded analysis. The CML-derived cell line, K562, has been widely used in research since it was originally established in 1975. The K562 karyotype however, has remained incomplete, and marker structures have never been fully described. Recent advances in fluorescence in situ hybridization (FISH) technology have introduced the possibility of chromosome classification based on 24-color chromosome painting (M-FISH). In this study, we report a clarified karyotype for K562 obtained by a combination of the following molecular cytogenetic techniques: comparative genomic hybridization (CGH), FISH mapping using locus-specific probes, and M-FISH. Multicolor FISH has identified the marker structures in this cell line. The characteristic marker chromosome in K562 has been confirmed by this study to be a der(18)t(1;18). Multicolor FISH confirmed the identity of marker structures partially identified by G-banding as der(6)t(6;6),der(17)t(9;17),der(21)t(1;21),der(5)t(5;6). In addition M-FISH has revealed a deleted 20q and a complex small metacentric marker comprised of material from chromosomes 1, 6, and 20. A cryptic rearrangement was revealed between chromosomes 12 and 21 that produced a structure that looks like a normal chromosome 12 homologue by G-banding analysis. Finally, M-FISH detected regions from chromosome 13 intercalated into two acrocentric markers.

Large deletions at the t(9;22) breakpoint are common and may identify a poor-prognosis subgroup of patients with chronic myeloid leukemia.

The hallmark of chronic myeloid leukemia (CML) is the BCR-ABL fusion gene, which is usually formed as a result of the t(9;22) translocation. Patients with CML show considerable heterogeneity both in their presenting clinical features and in the time taken for evolution to blast crisis. In this study, metaphase fluorescence in situ hybridization showed that a substantial minority of patients with CML had large deletions adjacent to the translocation breakpoint on the derivative 9 chromosome, on the additional partner chromosome in variant translocations, or on both. The deletions spanned up to several megabases, had variable breakpoints, and could be detected by microsatellite polymerase chain reaction in unfractionated bone marrow and purified peripheral blood granulocytes. The deletions were likely to occur early and possibly at the time of the Philadelphia (Ph) chromosome translocation: deletions were detected at diagnosis in 11 patients, were found in all Ph-positive metaphases, and were more prevalent in patients with variant Ph chromosomes. Kaplan-Meier analysis showed a median survival time of 36 months in patients with a deletion; patients without a detectable deletion survived > 90 months. The survival-time difference was significant on log-rank analysis (P =. 006). Multivariate analysis demonstrated that the prognostic importance of deletion status was independent of age, sex, percentage of peripheral blood blasts, and platelet count. Our data therefore suggest that an apparently simple, balanced translocation may result not only in the generation of a dominantly acting fusion oncogene but also in the loss of one or more genes that influence disease progression. (Blood. 2000;95:738-743)

Identification of multiple copies of a 20q-chromosome in a case of myelodysplastic syndrome: a FISH study.

In myelodysplastic syndromes (MDS) karyotypic aberrations identify subgroups of patients with distinct clinical-morphological features and can be relevant in risk assessment of developing leukemia. Often conventional cytogenetic analysis is not sufficiently informative due to the presence of partially or completely unrecognizable chromosome markers. By chromosome microdissection (MD) and fluorescence in situ hybridization (FISH) we investigated the nature of a karyotypic marker occurring in multiple copies in one case of MDS arisen in a patient previously treated for breast cancer. Results showed dicentrics derived from telomeric fusion between interstitially deleted 20q-chromosomes. The abnormal karyotype resulted into polysomy for a deleted chromosome 20q.

Comparative analysis of G-banding, chromosome painting, locus-specific fluorescence in situ hybridization, and comparative genomic hybridization in chronic myeloid leukemia blast crisis.

The molecular basis for blast transformation of chronic myeloid leukemia (CML) remains poorly understood. Cytogenetic alterations associated with CML blast crisis have previously been extensively studied by conventional G-banding analysis. However the complexity of some chromosome abnormalities or poor chromosome morphology or both has exceeded the resolution of G-banding analysis in a significant proportion of CML cases, and complex chromosome rearrangements have remained unidentified. In this study, comparative genomic hybridization (CGH) was used to elucidate genome imbalances in chronic phase or blast crisis samples or both from 12 CML patients. CGH and G-banding results were compared, and discrepancies were further clarified by using multipaint chromosome analysis and locus-specific DNA probes. No imbalances were detected in the 4 early disease phase samples studied. Eleven blast crisis samples were analyzed by G-banding and CGH, and the commonest genomic abnormality detected was overrepresentation of the long arm of chromosome 8, which was detected in 5 patients. This overrepresentation was attributable to trisomy 8 in 4 patients, whereas amplification of the entire long arm of chromosome 8 was detected in 1 patient. The formation of isochromosomes of the long arm of chromosome 8 was observed as a mechanism for gene amplification in this patient. Additional material originating from chromosome 8 was also observed intercalated into three marker chromosomes in peripheral blood metaphase spreads from this patient. These markers may further define areas on chromosome 8 that harbor oncogenes implicated in transformation of chronic myeloid leukemia.

Comparative genomic hybridization: a comparison with molecular and cytogenetic analysis.

Comparative genomic hybridization (CGH) is a powerful technique for detecting copy number changes throughout the genome. We describe the development of a versatile image analysis program for CGH studies. Several methods for the production of metaphases which give optimum hybridization signals have also been assessed. CGH analysis was performed on DNA samples from several different and clinically relevant specimens: amniotic fluid cells trisomic for a single chromosome, lymphoblastoid cell lines with abnormalities involving single chromosome bands, malignant cell lines and biopsy material from primary ovarian carcinomas. The results were compared with those derived from G-banding, chromosome painting, and molecular genetic techniques. Our data demonstrate that CGH was able to detect a wide range of quantitative genetic alterations including duplication or deletion of single chromosome bands. CGH analysis also indicated the presence of genetic abnormalities that were not detected by other cytogenetic or molecular approaches. Moreover, our CGH methodology allowed the ready comparison of CGH results from different tumors, a process which greatly facilitated identification of shared genetic changes.

Molecular genetics and cytogenetics of myeloproliferative disorders.

The myeloproliferative disorders are believed to represent clonal malignancies resulting from transformation of a pluripotent stem cell. X-inactivation patterns of peripheral blood cells have been proposed as a useful diagnostic tool but this method is limited by the finding of a clonal X-inactivation pattern in a significant proportion of normal elderly women. There is no pathognomonic chromosomal abnormality associated with the myeloproliferative disorders. However, consistent acquired cytogenetic changes include del(20q), del(13q), trisomy 8 and 9 and duplication of segments of 1q, all of which have been observed at diagnosis or before cytoreductive therapy and therefore represent early lesions which contribute to the pathogenesis of these disorders. Although, the acquired molecular defects underlying most myeloproliferative disorders have not yet been elucidated, translocations associated with the rare 8p11 syndrome have permitted identification of a novel fusion protein. The role of a number of candidate genes in the other myeloproliferative disorders has also been studied, but no mutations have been identified so far. It is likely that a number of genes will be involved, given the varied phenotypes of the diseases. Identification of causal genes will be of considerable interest to both clinicians, who currently lack a specific and sensitive diagnostic test, and scientists interested in fundamental issues of stem cell behaviour.

Improved sensitivity of BCR-ABL detection: a triple-probe three-color fluorescence in situ hybridization system.

Chronic myeloid leukemia is a clonal stem cell disorder associated with the Philadelphia (Ph) translocation [t(9;22) (q34;q11)]. As a result of the Ph translocation, parts of the ABL and BCR genes become fused. Cytogenetic quantification of Ph+ metaphases can be used to monitor patient response to treatment but is of limited sensitivity and applies only to cycling cells. Fluorescence in situ hybridization (FISH) with probes from the BCR and ABL regions can also identify the Ph translocation in interphase cells. Established systems for the detection of fusion genes by FISH rely on colocalization of two different probes but are associated with a high rate of false-positive results. We have introduced a third probe labeled with a different fluorochrome to create a triple-probe/three-color system that permits identification of both the Ph chromosome and the derivative 9 chromosome in Ph+ cells. This system was used to determine the frequency of interphase cells carrying the BCR-ABL fusion gene in bone marrow and peripheral blood granulocytes from patients showing variable cytogenetic responses to interferon. Our data show that the triple-probe/three-color approach allows highly sensitive detection of residual disease. Moreover, this method is readily applicable to the analysis of other chromosome translocations.

Detection of chromosome 20q deletions in bone marrow metaphases but not peripheral blood granulocytes in patients with myeloproliferative disorders or myelodysplastic syndromes.

Myeloproliferative disorders and myelodysplastic syndromes arise in multipotent progenitors and may be associated with chromosomal deletions that can be detected in peripheral blood granulocytes. We present here seven patients with myeloproliferative disorders or myelodysplastic syndromes in whom a deletion of the long arm of chromosome 20 was detectable by G-banding and/or fluorescence in situ hybridization in most or all bone marrow metaphases. However, in each case, microsatellite polymerase chain reaction (PCR) using 15 primer pairs spanning the common deleted region on 20q showed that the deletion was absent from most peripheral blood granulocytes. The human androgen receptor clonality assay was used to show that the vast majority of peripheral blood granulocytes were clonal in all four female patients. This represents the first demonstration that the 20q deletion can arise as a second event in patients with pre-existing clonal granulopoiesis. Microsatellite PCR analysis of whole bone marrow from two patients was consistent with cytogenetic studies, a result that suggests that cytogenetic analysis was not merely selecting for a minor subclone of cells carrying the deletion. Furthermore, in one patient, the deletion was present in both erythroid and granulocyte/monocyte colonies. This implies that the absence of the deletion in most peripheral blood granulocytes did not reflect lineage restriction of the progenitors carrying the deletion but may instead result from other selective influences such as preferential retention/destruction within the bone marrow of granulocytes carrying the deletion.

The human CD40 gene lies within chromosome 20q deletions associated with myeloid malignancies.

Deletions of chromosome 20q are associated with myeloid malignancies and have been previously shown to arise in a multipotent progenitor of both myeloid and B cells. However, B-cell differentiation from the abnormal progenitor was impaired. The CD40 antigen is a surface glycoprotein which is expressed in B cells and haemopoietic stem cells and is important for B-cell growth and development. Following the recent mapping of CD40 to chromosome 20q we sought to determine its position relative to 20q deletions. Analysis of lymphoblastoid cell lines carrying 20q deletions placed CD40 within a 19-21 cM interval which is almost coincidental with the common deleted region defined by previous analysis of patient samples. Our results raise the possibility that genetic alteration of this locus may contribute to the pathogenesis of myeloid disorders associated with 20q deletions.