Jumping Translocations of Chromosome 1q in Multiple Myeloma: Evidence for a Mechanism Involving Decondensation of Pericentromeric Heterochromatin

Frequent gain of chromosome band 1q21 in plasma-cell dyscrasias detected by fluorescence in situ hybridization: incidence increases from MGUS to relapsed myeloma and is related to prognosis and disease progression following tandem stem-cell transplantation

Using fluorescence in situ hybridization we investigated amplification of chromosome band 1q21 (Amp1q21) in more than 500 untreated patients with monoclonal gammopathy of undetermined significance (MGUS; n = 14), smoldering multiple myeloma (SMM; n = 31), and newly diagnosed MM (n = 479) as well as 45 with relapsed MM. The frequency of Amp1q21 was 0% in MGUS, 45% in SMM, 43% in newly diagnosed MM, and 72% in relapsed MM (newly diagnosed versus relapsed MM, P < .001). Amp1q21 was detected in 10 of 12 patients whose disease evolved to active MM compared with 4 of 19 who remained with SMM (P < .001). Patients with newly diagnosed MM with Amp1q21 had inferior 5-year event-free/overall survival compared with those lacking Amp1q21 (38%/52% versus 62%/78%, both P < .001). Thalidomide improved 5-year EFS in patients lacking Amp1q21 but not in those with Amp1q21 (P = .004). Multivariate analysis including other major predictors revealed that Amp1q21 was an independent poor prognostic factor. Relapsed patients who had Amp1q21 at relapse had inferior 5-year postrelapse survival compared with those lacking Amp1q21 at relapse (15% versus 53%, P = .027). The proportion of cells with Amp1q21 and the copy number of 1q21 tended to increase at relapse compared with diagnosis. Our data suggest that Amp1q21 is associated with both disease progression and poor prognosis.

Using Genomics to Identify High-Risk Myeloma after Autologous Stem Cell Transplantation

Multiple myeloma is a malignancy of antibody-secreting plasma cells that expand in the bone marrow. Although high-dose therapy/autologous stem cell transplantation has become the standard of care for patients with multiple myeloma, survival is highly variable and can range from a few years to >10 years after diagnosis. Application of high-throughput genomics on a large uniformly untreated cohort of patients has revealed that activation of 1 of the 3 cyclin D genes is a universal initiating event in this disease and that acquisition of abnormalities of chromosome 1 leads to activation of CKS1B, a regulator of p27Kip1 degradation. Synergy between cyclin D2 and CKS1B, but not cyclin D1 and CKS1B, may lead to early treatment failure.

Jumping translocations in multiple myeloma

Jumping translocations (JT) have been defined as nonreciprocal translocations involving a same donor chromosome arm or chromosome segment onto two or more recipient chromosomes in different cell lines in the same patient, leading to a mosaic karyotype. This definition has been expanded to also include extra copies of a same donor segment on different recipient chromosomes in a single clone. Six patients with multiple myeloma and JT involving chromosome arm 1q were identified among 37 patients presenting with chromosome 1 abnormalities. All six patients had an advanced disease and a short survival. The literature review allowed us to identify 24 additional patients with JT. Chromosomes 16 and 19 were the recipients in 11 (45.8%) and 6 (25%) of these 24 patients, respectively. Breakpoints on the recipient chromosomes were pericentromeric in 46.2% and telomeric in 40.4% of the breakpoints recorded. Since telomeres are made of (TTAGGG)n tandem DNA repeats that are also found in the pericentromeric heterochromatic regions (interstital telomeric sequences), it is presumed that jumping translocations arise through illegimate recombination between telomere repeat sequences and interstitial telomeric sequences.

Genetics of multiple myeloma

In recent years, we have seen an explosion in knowledge of the genetics and cytogenetics of the plasma-cell neoplasms. This chapter will deal with these advances and will place them in the integrative context of the pathophysiologic basis of the disease, and will discuss the important clinical implications of these abnormalities. We have learned that myeloma can be classified into increasingly definable subgroups that follow a basic global hierarchical grouping. All gene expression profiling strategies have come to similar conclusions and confirm the subgroups previously identified by karyotype, molecular cytogenetics and other genetic studies. At the top level there are two major pathogenetic pathways for the development of plasma cell tumors: one that is associated with hyperdiploidy and one that is characterized by the presence of chromosome translocations involving the immunoglobulin heavy chain locus (IgH). These translocations are seen in up to 60% of patients, but involve a common recurrent chromosome partner in only 40-50% of patients. Several genetic markers are now shown to be associated with a shortened survival. Of these, the most common ones include abnormalities (deletion and monosomy) of chromosome 13, the global state of hypodiploidy and abnormalities of chromosome 1. Many of the translocations observed in MM are also seen in monoclonal gammopathy of undetermined significance (MGUS), even in individuals without progression to full malignant disease for many years. The identification of critical genetic lesions will pave the way for the development of disease-targeted therapy.

Leukemic recombinations involving heterochromatin in myeloproliferative disorders with t(1;9)

The unbalanced t(1;9) is a rare, recurrent rearrangement in polycythemia vera (PV) resulting in trisomy of both 1q and 9p arms, whereas a balanced t(1;9)(q12;q12), to our knowledge, has never been reported before. We studied two patients with PV and one with idiopathic myelofibrosis bearing an unbalanced t(1;9) and one patient with essential thrombocythemia with a balanced t(1;9). In all cases fluorescence in situ hybridization showed that the breakpoints were located within the satellite II family of heterochromatin of chromosome 1 and the satellite III of chromosome 9. Heterochromatin breakage and reunion produce the unbalanced t(1;9) and may contribute to a gene dosage effect due to gains of 1q and 9p. Case 4 with the balanced t(1;9), however, suggests that translocation of heterochromatin close to critical genes could interfere with their function. The molecular event underlying juxtaposition of satellite II of chromosome 1 and the satellite III of chromosome 9 remains to be elucidated.

Prognostic and Therapeutic Significance of Myeloma Genetics and Gene Expression Profiling

Molecular diagnostic tools and novel therapeutics now offer the potential for accurate prognostic and personalized treatment road maps for patients with multiple myeloma (MM). We will review the evidence and provide specific recommendations for routine clinical molecular genetic testing and use of such information to guide therapeutic decision making. In particular, the negative prognostic impact of specific IgH translocations such as the t(4;14), t(14;16), chromosome 13 deletion by conventional cytogenetics and loss of 17p13 by interphase fluorescence in situ hybridization are now established. Preliminary gene expression profiling studies have also demonstrated that individual genes (CSK1-B) or groups of genes can define prognosis with greater accuracy than conventional genetic markers and can provide pharmacogenomic and biologic insight into the pathophysiology, therapeutics, and future targets of myeloma. Importantly, we recommend that all clinical trials now adopt routine genetic testing and risk stratification.

Comparative genomic hybridisation identifies two variants of smoldering multiple myeloma

Two variants of smoldering multiple myeloma (SMM) have been recognised: (i) an evolving type, characterised by a progressive increase in the M-protein size and short time to progression to overt multiple myeloma (MM) and (ii) a non-evolving type, with a long-lasting, stable M-protein and longer time to progression. Comparative genomic hybridisation (CGH) analyses in both subtypes of SMM (seven evolving and eight non-evolving SMM) were performed. Evolving SMM showed cytogenetic changes consistent with those found in de novo symptomatic MM (1q gains, chromosome 13 deletions) while the non-evolving variant showed no 1q gains and deletions were uncommon.

Evidence for telomeric fusions as a mechanism for recurring structural aberrations of chromosome 11 in giant cell tumor of bone

Giant cell tumor of bone (GCTB) is a benign but often aggressive tumor with a tendency toward local recurrence. Telomeric associations (tas) or telomeric fusions are common cytogenetic findings that have been implicated in the initiation of chromosome instability and tumorigenesis. We performed cytogenetic studies on 5 cases of GCTB to further characterize chromosome aberrations in these tumors. Four of the 5 cases showed abnormal karyotypes with clonal telomeric fusions involving chromosome 11. In 3 cases, the telomeric fusions of 11pter were apparently the precursor lesions to the progression of sub-clones with structural chromosome aberrations of 11p. Two tumors demonstrated a similar pattern of progression resulting in whole arm losses of 11p, including sub-clones with both whole-arm unbalanced translocations and whole-arm deletions. A third tumor with clonal tas of 11pter showed 2 additional subclones, one with ring chromosome 11 and the other with an extra copy of 1q. To our knowledge, the 2 cases with del(11)(p11) represent the first report of a recurring structural chromosome aberration in GCTB. These findings support the concept that telomeric instability is responsible for a large degree of intratumor heterogeneity and serves as a precursor lesion to subsequent clonal structural aberrations of chromosome 11 in GCTB.

Duplication of chromosome arms 9q and 11q: evidence for a novel, 14q32 translocation-independent pathogenetic pathway in multiple myeloma

14q32 translocations [t(14q)] represent critical but not universal events in multiple myeloma (MM). Gains of chromosome arms 1q, 9q, and 11q (+1q, +9q, and +11q) have recently been identified as frequent aberrations in this disease, but their pathogenetic significance remains unclear. We studied a series of 108 MM patients using fluorescence in situ hybridization and DNA probes mapping to chromosome bands 1q21, 9q34, 11q25, 13q14, and 14q32. Three subsets of tumors were defined: (1) MM+/+ (detection of +9q and +11q; 43.5% of cases), (2) MM+/- (+9q or +11q; 21.3%), and (3) MM-/- (neither +9q nor +11q; 35.2%). The incidence of t(14q) was significantly different in these subgroups: 23% in MM+/+, 56% in MM+/-, and 89% in MM-/-. Deletion of 13q (13q-) also was significantly less frequent in MM+/+ (23%) than in MM+/- and MM-/- (36% and 63%, respectively). The nonrandom distribution of chromosomal aberrations in the present series of MM tumors points to a novel, 14q32 translocation-independent pathogenetic pathway in plasma cell neoplasms.

Jumping translocation of 1q in a BCR/ABL-positive acute lymphoblastic leukemia

Jumping translocations (JT) are rare chromosomal abnormalities in which an identical copy of a chromosomal region (donor) is translocated to a different chromosome (acceptor). Chromosome 1 is often involved as donor chromosome. JTs of the long arm of chromosome 1 (1q) or parts of it are associated with a poor outcome. We report on a 72-year-old male patient with a BCR/ABL1 rearrangement positive acute lymphoblastic leukemia (common ALL, or c-ALL; FAB L2 morphology) and with additional structural and numeric aberrations. Four aberrant clones were observed after conventional cytogenetic analysis. Three of the four clones showed a JT with 1q as donor and 3q, 8q, and 22q as acceptors. To the best of our knowledge, neither JT between 1q and chromosome 3 nor JT between 1q and chromosome 22 have been described in c-ALL. This report emphasizes the frequent involvement of 1q in JT and the association with a poor prognosis.

Delineation of distinct subgroups of multiple myeloma and a model for clonal evolution based on interphase cytogenetics

To delineate multiple myeloma (MM) subgroups and their clonal evolution, we analyzed 81 newly diagnosed patients by interphase fluorescence in situ hybridization using a comprehensive probe set for 10 chromosomes and two IGH rearrangements. A median of 5 probes per patient displayed aberrant signal numbers (range, 1-10). Additional copies most frequently found were for 15q22, 19q13, 9q34, 11q23, and 1q21. Losses commonly observed were of 13q14.3, 17p13, and 22q11. Predominance of gain or loss was quantified by a copy number score (CS) for each patient. Two peaks (CS = +3 and CS = 0) were found by plotting patient copy number scores over CS values corresponding to hyperdiploid and nonhyperdiploid MM. Cluster analysis revealed four major branches: (i) gain of 9q, 15q, 19q, and/or 11q; (ii) deletion of 13q and t(4;14); (iii) t(11;14); and (iv) gain of 1q. Statistical modeling of an oncogenetic tree indicated that early independent events were gain of 15q/9q and/or 11q, t(11;14); deletion of 13q followed by t(4;14); and gain of 1q. Aberrations of 17p13, 22q11, 8p12, and 6q21 were found as subsequent events. MM with gain of 1q was delineated as a subentity with significantly higher beta-2-microglobulin and lower hemoglobin levels, indicating a poor prognosis. From our results, we propose a model of MM for clonal evolution.

Centromeric breakage and highly rearranged chromosome derivatives associated with mutations ofTP53 are common in therapy-related MDS and AML after therapy with alkylating agents: An M-FISH study

Multicolor fluorescence in situ hybridization (M-FISH) was performed on bone marrow cells of 116 unselected cases of therapy-related myelodysplasia (t-MDS) or acute myeloid leukemia (t-AML), and the results were compared with those of previously performed with G-banding. Among 18 patients with a normal karyotype, no cryptic chromosome aberrations were observed with M-FISH. In 56 patients with a previously solved abnormal karyotype, only 17 new aberrations were identified, whereas 153 new aberrations were detected by M-FISH in 42 patients with a previously unsolved karyotype. In total, 112 of the new aberrations were unbalanced translocations, and only nine were balanced translocations. A clustering of breakpoints was observed in the centromeric or pericentromeric region of chromosomes 1, 5, 7, 13, 17, 21, and 22 in 48 of 98 patients with t-MDS and t-AML and an abnormal karyotype, and was related to previous therapy with alkylating agents. In seven of eight patients with chromosome derivatives containing material from three or more chromosomes or having sandwichlike chromosomes, those made up of several small interchanging layers of material from two chromosomes showed mutations of TP53. M-FISH had little impact on the prognostic classification of t-MDS and t-AML, as only three patients changed prognostic groups as a result of M-FISH.

Pathogenesis of jumping translocations: a molecular cytogenetics study

BACKGROUND/AIMS

Jumping translocations are rare cytogenetic aberrations in haematological malignancies, the pathogenesis of which remains to be fully characterised. We investigated the mechanism of formation of jumping translocations in a case of adult common acute lymphoblastic leukaemia (ALL) positive for the Ph translocation.

METHODS

Interphase and metaphase fluorescence in situ hybridisation (FISH) was performed using several probe systems. Results were correlated with findings on conventional cytogenetics. Granulocytes, T-cells and leukaemic B-cells in peripheral blood were sorted by immunomagnetic method and the terminal restriction fragment (TRF) length of these cellular populations was determined by Southern blot analysis.

RESULTS

Duplicated BCR-ABL fusion signals were found on a dic(14;22)der(22)t(9;22) chromosome. Clonal jumping translocations, existing as evolutionary changes, involved the donor chromosomal segment distal to 1q12 jumping onto the telomere ends of 11q, 15p, 19p and 20p. Telomere length was decreased in the neoplastic B-cell population and contributed to the formation of the dicentric chromosome that showed absence of telomere repeats at fusion ends. Subsequent pericentromeric heterochromatin decondensation of chromosome 1q occurred, and this donor segment was randomly fused to the shortened telomere ends of non-homologous chromosomes.

CONCLUSIONS

Both telomere shortening and pericentromeric heterochromatin decondensation contribute to the formation of jumping translocations, which is most probably a multi-stage process.

Overexpression of PDZK1 within the 1q12-q22 amplicon is likely to be associated with drug-resistance phenotype in multiple myeloma

We investigated DNA copy number aberrations in 37 cell lines derived from multiple myelomas (MMs) using comparative genomic hybridization, and 11 (29.7%) showed high-level gain indicative of gene amplification at 1q12-q22. A corresponding transcriptional mapping using oligonucleotide arrays extracted three up-regulated genes (IRTA2, PDZK1, and S100A6) within the smallest region of overlapping in amplifications. Among them PDZK1 showed amplification and consequent overexpression in the MM cell lines. Amplification of PDZK1 was observed in primary cases of MM as well. MM cell lines with amplification of PDZK1 exhibited the resistance to melphalan-, cis-platin-, and vincristin-induced cell death compared with MM cell lines without its amplifications. Furthermore, down-regulation of PDZK1 with an anti-sense oligonucleotide sensitized a cell line KMS-11 to melphalan, cis-platin, and vincristin. Taken together, our results indicate that PDZK1 is likely to be one of targets for 1q12-q22 amplification in MM and may be associated with the malignant phenotype, including drug resistance, in this type of tumor.

Cytogenetic and fluorescence in situ hybridization studies in 60 patients with multiple myeloma and plasma cell leukemia

We report cytogenetic results in a series of 60 patients affected with multiple myeloma (MM) and plasma cell leukemia (PCL) and compare the results with those previously reported. In our series, a total of 41% of MM patients and 71% of PCL patients displayed chromosome abnormalities. To evaluate the clinical value of monosomy 18, we obtained fluorescence in situ hybridization results (using centromeric probe for chromosome 18) of 22 MM patients who displayed a normal karyotype. Monosomy 18 was present in 3 of 22 patients (14%). Using conventional cytogenetics, we detected monosomy 18 in one patient affected with PCL. Two of four cases with monosomy 18 followed an aggressive course, with overall survival of 1 and 9 months. The remaining two are in follow-up and remain stable. The association of monosomy 18 with IgA subtype predominance and poor prognosis was not observed in this series of MMs and PCLs. Although these results do not confirm our previous hypothesis, further observations of this group of patients (with monosomy 18) regarding malignant transformation is warranted.

Genomic instability in multiple myeloma: Evidence for jumping segmental duplications of chromosome arm 1q

Multiple myeloma (MM) is a malignant plasma cell disorder characterized by complex karyotypes and chromosome 1 instability at the cytogenetic level. Chromosome 1 instability generally involves partial duplications, whole-arm translocations, or jumping translocations of 1q, identified by G-banding. To characterize this instability further, we performed spectral karyotyping and fluorescence in situ hybridization with probes for satII/III (1q12), BCL9 (1q21), and IL6R (1q21) on the karyotypes of 44 patients with known 1q aberrations. In eight patients, segmental duplication of 1q12-21 and adjacent bands occurred on nonhomologous chromosomes. In five cases, the 1q first jumped to a nonhomologous chromosome, after which the 1q12-21 segment again duplicated itself 1-3 times. In three other cases, segmental duplications occurred after the 1q first jumped to a nonhomologous chromosome, where the proximal adjacent nonhomologous chromosome segment was duplicated prior to the 1q jumping or inserting itself into a new location. These cases demonstrate that satII/III DNA sequences are not only associated not only with the duplication of adjacent distal chromosome segments after translocation, but are also associated with the duplication and jumping/insertion of proximal nonhomologous chromosome segments. We have designated this type of instability as a jumping segmental duplication.

MDS-type abnormalities within myeloma signature karyotype (MM-MDS): only 13% 1-year survival despite tandem transplants

Cytogenetic abnormalities (CA), especially of chromosome 13, have been used to identify a subgroup of previously untreated multiple myeloma (MM) patients with very poor prognosis despite high-dose therapy (HDT). We examined the prognostic implications of CA in 1000 MM patients receiving melphalan-based tandem autotransplants (median follow-up, 5 years). Negative consequences for both overall survival (OS) and event-free survival (EFS) in the presence of any CA were confirmed, especially when detected within 3 months of HDT. In the context of standard prognostic factors (SPF), 'MM-MDS' (MM karyotype that contains, in addition, CA typical of MDS) imparted a poor OS and EFS, after adjusting for any CA and all individual CA. One-year mortality was also high, especially for the MM-MDS subgroup with trisomy 8 within a MM signature karyotype (87%vs 34% in its absence, P < 0.001). No patient remained event free 5 years post transplant in the presence of these baseline high-risk CA. However, certain trisomies (e.g. chromosomes 7 and 9) and del 20 had favourable clinical consequences. The higher risk that is associated with CA compared with SPF justifies routine cytogenetic studies in all patients with MM at diagnosis and whenever additional treatment decisions are considered, such as in planning HDT either for initial response consolidation, at the time of primary unresponsiveness to induction therapy, or at relapse.

Telomerase and telomere length in multiple myeloma: correlations with disease heterogeneity, cytogenetic status, and overall survival

We have investigated the significance of telomerase activity (TA) and telomere length (TL) in multiple myeloma (MM). The analyses were undertaken on CD138+ MM cells isolated from the marrow of 183 patients either at diagnosis or in relapse. There was heterogeneity in telomerase expression; 36% of the patients had TA levels comparable to those detected in normal plasma cells, and 13% of patients had levels 1- to 4-fold greater than in a neuroblastoma cell line control. The TL of MM cells was significantly shorter than that of the patients' own leukocytes; in 25% of patients, the TL measured less than 4.0 kbp. Analysis of TL distribution indicated selective TA-mediated stabilization of shorter telomeres when mean TL fell below 5.5 kbp. Unusually long (10.8-15.0 kbp) telomeres were observed in 7 patients, and low TA was observed in 5 of 7 patients, suggesting the operation of a TA-independent pathway of telomere stabilization. A strong negative correlation existed between TA and TL or platelet count. TL negatively correlated with age and with interleukin-6 (IL-6) and beta2-microglobulin levels. Various cytogenetic abnormalities, including those associated with poor prognosis, strongly correlated with TA and, to a lesser extent, with short TL. High TA and short TL defined a subgroup of patients with poor prognosis. At 1 year the survival rate in patients with TA levels lower than 25% of neuroblastoma control and TL greater than 5.5 kbp was 82%, whereas in patients with higher TA and shorter TL the survival rate was 63% (P =.004). The 2-year survival rate for patients with TA levels lower than 25% was 81%, and it was 52% in those with higher TA levels (P <.0001).

Genome architecture catalyzes nonrecurrent chromosomal rearrangements

To investigate the potential involvement of genome architecture in nonrecurrent chromosome rearrangements, we analyzed the breakpoints of eight translocations and 18 unusual-sized deletions involving human proximal 17p. Surprisingly, we found that many deletion breakpoints occurred in low-copy repeats (LCRs); 13 were associated with novel large LCR17p structures, and 2 mapped within an LCR sequence (middle SMS-REP) within the Smith-Magenis syndrome (SMS) common deletion. Three translocation breakpoints involving 17p11 were found to be located within the centromeric alpha-satellite sequence D17Z1, three within a pericentromeric segment, and one at the distal SMS-REP. Remarkably, our analysis reveals that LCRs constitute >23% of the analyzed genome sequence in proximal 17p--an experimental observation two- to fourfold higher than predictions based on virtual analysis of the genome. Our data demonstrate that higher-order genomic architecture involving LCRs plays a significant role not only in recurrent chromosome rearrangements but also in translocations and unusual-sized deletions involving 17p.

Satellite DNA hypomethylation in karyotyped Wilms tumors

Previously, a high percentage of Wilms tumors was found to be hypomethylated in the unusually long region of pericentromeric satellite DNA on chromosome 1. We now show that these pediatric cancers are also frequently hypomethylated in centromeric satellite DNA throughout the genome and compare satellite DNA hypomethylation with chromosome rearrangements. Relative to normal somatic tissues, 83% of the tumors were hypomethylated in centromeric satellite alpha DNA. This was assessed by blot hybridization under low-stringency conditions after digestion with CpG methylation-sensitive restriction endonucleases. Similar results were obtained with different enzymes, indicating generalized hypomethylation of centromeric DNA. Hypomethylation of another heterochromatic sequence, juxtacentromeric satellite 2 DNA of chromosome 1, was observed in 51% of the tumors. By cytogenetic analysis, rearrangements in the centromeric or juxtacentromeric heterochromatin of chromosome 1 were the most frequent structural aberration and were seen in 14% of the tumors. Tumors with such rearrangements had hypomethylation of satellite DNA in the pericentromeric region. These results show a high degree of targeting of DNA hypomethylation to centromeric and juxtacentromeric satellite DNA sequences in cancer and are consistent with satellite DNA hypomethylation contributing to, but not sufficing for, karyotypic instability in cancer and possibly playing other roles in carcinogenesis.

A pooled analysis of karyotypic patterns, breakpoints and imbalances in 783 cytogenetically abnormal multiple myelomas reveals frequently involved chromosome segments as well as significant age- and sex-related differences

The cytogenetic features (ploidy, complexity, breakpoints, imbalances) were ascertained in 783 abnormal multiple myeloma (MM) cases to identify frequently involved chromosomal regions as well as a possible impact of age/sex. The series included MM patients from the Mitelman Database of Chromosome Aberrations in Cancer and from our own laboratory. Hyperdiploidy was most common, followed by hypodiploidy, pseudodiploidy and tri-/tetraploidy. Most cases were complex, with a median of eight changes per patient. The distribution of modal numbers differed between younger and older patients, but was not related to sex. No sex- or age-related differences regarding the number of anomalies were found. The most frequent genomic breakpoints were 14q32, 11q13, 1q10, 8q24, 1p11, 1q21, 22q11, 1p13, 1q11, 19q13, 1p22, 6q21 and 17p11. Breaks in 1p13, 6q21 and 11q13 were more common in the younger age group. The most frequent imbalances were + 9, - 13, + 15, + 19, + 11 and - Y. Trisomy 11 and monosomy 16 were more common among men, while -X was more frequent among women. Loss of Y as the sole change and + 5 were more common in elderly patients, and - 14 was more frequent in the younger age group. The present findings strongly suggest that some karyotypic features of MM are influenced by endogenous and/or exogenous factors.

A novel tumorigenic human prostate epithelial cell line (M2205): molecular cytogenetic characterization demonstrates C-MYC amplification and jumping translocations

The paucity of cell lines from early-stage prostate cancer tumors has hindered the recognition of genetic and cellular changes that are associated with the acquisition of tumorigenesis. We describe the chromosomal complement of a novel tumorigenic prostate epithelial cell subline, called M2205, that acquired only three new, consistent chromosomal changes (from those present in the SV40T antigen immortalized parental cell line, P69SV40TAg) when it attained tumor-forming potential. The consistent changes, which were fully characterized using GTG-banding, CBG-banding, silver staining, fluorescence in situ hybridization (FISH), comparative genomic hybridization (CGH), and spectral karyotyping (SKY), involved segmental jumping translocations and resulted in gains in the copy number of genes located on the distal long arm of chromosome 8 (8q22 to 8q24.3), including c-myc. Furthermore, the jumping translocations also resulted in ribosomal genes being present in multiple, tandem copies next to the chromatin from 8q. Given the relatively small number of cytogenetic changes present, this subline provides a means for better understanding the cellular changes associated with the acquired chromosomal imbalances. Further studies of this subline could also provide insight as to the mechanism or mechanisms leading to the formation of jumping translocations, as well as potential position effects resulting from the relocation of ribosomal genes next to other cellular genes or oncogenes.

Chromosome abnormalities clustering and its implications for pathogenesis and prognosis in myeloma

The nonrandom recurrent nature of chromosome abnormalities in myeloma suggests a role for them in disease pathogenesis. We performed a careful cytogenetic analysis of patients with abnormal karyotypes (n = 254), to discern patterns of association, search for novel abnormalities and elucidate clinical implications. Patients with karyotypic abnormalities suggestive of myelodysplasia/acute leukemia were excluded. In this study we compared survival by abnormality only between patients with abnormal karyotypes. Patients with abnormalities were more likely to have features of aggressive disease as compared to all other patients without abnormalities entered into the myeloma database (lower hemoglobin, higher beta(2)-microglobulin, labeling-index and plasmocytosis; all P < 0.0001). Several groups of patients could be readily identified; hypodiploid (22%), pseudodiploid (36%), hyperdiploid (31%) and near-tetraploid (11%). Clustering associations were seen among several trisomies and monosomy of chromosome 13 and 14. Several monosomies (-2, -3, -13, -14 and -19), 1p translocations/ deletions, and hypodiploidy were associated with a significantly shorter survival. Trisomy of chromosome 13 was rare ( <2%). Even among patients with abnormal karyotypes, specific chromosome abnormalities can impart biologic variability in myeloma, including several monosomies, hypodiploidy and abnormalities of 1p.

The biology and cytogenetics of multiple myeloma

Despite the advances in our knowledge of myeloma cell biology, our understanding of myeloma pathogenesis is still incomplete. In this review, we present a summary of the cellular and molecular aspects of B-cell development and immunoglobulin (lg) gene rearrangement which have been important in defining the characteristics of the myeloma plasma cell (MPC). The PMC has undergone variable gene recombination, somatic hypermutation and isotype switching, and is therefore at a postgerminal center stage of development. The finding of preswitch clonal cells and isotype variants have raised interesting questions about the cell of origin of myeloma, for which no conclusive data is as yet available. However much information has been obtained about the chromosomal and genetic aberrations in myeloma, including monosomy 13, Ig heavy chain (IgH) switch region translocations, numerical abnormalities and a multitude of heterogeneous changes. A variety of techniques have been developed to overcome the insensitivity of conventional karyotyping, utilizing molecular cytogenetic strategies ranging from the delineation of precise loci by fluorescent in situ hybridization, a more "global" assessment of the genome by multicolor spectral karyotyping, to the quantitation of chromosomal material of specific origin by comparative genomic hybridization. Whether the abnormalities detected represent oncogenic insults, are involved in disease progression or are simply "by-products" of genetic instability is still unclear. For IgH translocations, the role of candidate genes such as Cyclin D1 and FGFR3 has been studied extensively by quantitating their expression and assessment of their oncogenicity (e.g. for FGFR3) in animal models. The significance of other aberrations such as c-myc, ras and p53 has also been investigated. With the advent of oligonucleotide microarrays, the expression of thousands of genes can be efficiently examined. So far, this approach seems promising in defining subgroups of different disease behavior, and may highlight specific genes and molecular mechanisms which are important in myeloma pathogenesis.

Molecular cytogenetic analysis of the monoblastic cell line U937. karyotype clarification by G-banding, whole chromosome painting, microdissection and reverse painting, and comparative genomic hybridization

Previous reports on the analysis of the human monoblastic cell line U937 had described several sublines containing unidentified rearrangements and marker chromosomes. In order to determine the true nature of the rearrangements, conventional banding analysis was carried out with various combinations of molecular cytogenetic techniques: comparative genomic hybridization, fluorescence in situ hybridization (FISH) with whole chromosome painting probes, and microdissection and reverse painting FISH. The origins of the marker chromosomes were identified and the composite karyotype is described.

DNA hypomethylation, cancer, the immunodeficiency, centromeric region instability, facial anomalies syndrome and chromosomal rearrangements

Inadequate attention has been paid to the frequent and often extensive cancer-associated DNA hypomethylation. This hypomethylation usually includes undermethylation of certain DNA repeats in constitutive heterochromatin, although it is not limited to such sequences. Many cancers display an overall deficiency in the levels of genomic 5-methylcytosine compared to a variety of normal postnatal somatic tissues. The immunodeficiency, centromeric region instability, facial anomalies (ICF) syndrome, a rare recessive DNA methyltransferase deficiency disease, results in a small decrease in the extent of global genomic methylation. In ICF, DNA hypomethylation is targeted to the satellite DNA in juxtacentromeric (centromere-adjacent) heterochromatin of chromosomes 1 and 16 (1qh and 16qh), which are prone to rearrangements in ICF lymphoid cells. Also, 1qh and 16qh DNA sequences frequently are hypomethylated in human cancers and rearrangements in their vicinity are overrepresented in cancers. These often lead to chromosome arm imbalances and gene dosage imbalances that could participate in carcinogenesis. Studies of ICF cells suggest that hypomethylation in the normally highly methylated 1qh and 16qh regions predisposes to heterochromatin decondensation in these regions, which in turn leads to elevated levels of rearrangements. Studies of ICF cells also suggest that some of these rearrangements, namely multiradial chromosomes with multiple arms joined in the pericentromeric region, may be unstable intermediates in formation of more stable pericentromeric rearrangements in cancer. Microarray gene expression analysis on ICF and normal lymphoblastoid cell lines suggests that this hypomethylation also may affect gene expression elsewhere in the genome.

A human Mix-like homeobox gene MIXL shows functional similarity to Xenopus Mix.1

Molecular events involved in specification of early hematopoietic system are not well known. In Xenopus, a paired-box homeodomain family (Mix.1-4) has been implicated in this process. Although Mix-like homeobox genes have been isolated from chicken (CMIX) and mice (Mml/MIXL1), isolation of a human Mix-like gene has remained elusive. We have recently isolated and characterized a novel human Mix-like homeobox gene with a predicted open reading frame of 232 amino acids designated the Mix.1 homeobox (Xenopus laevis)-like gene (MIXL). The overall identity of this novel protein to CMIX and Mml/MIXL1 is 41% and 69%, respectively. However, the identity in the homeodomain is 66% to that of Xenopus Mix.1, 79% to that of CMIX, and 94% to that of Mml/MIXL1. In normal hematopoiesis, MIXL expression appears to be restricted to immature B- and T-lymphoid cells. Several acute leukemic cell lines of B, T, and myeloid lineage express MIXL suggesting a survival/block in differentiation advantage. Furthermore, Xenopus animal cap assay revealed that MIXL could induce expression of the alpha-globin gene, suggesting a functional conservation of the homeodomain. Isolation of the MIXL gene is the first step toward understanding novel regulatory circuits in early hematopoietic differentiation and malignant transformation.

Uncovering novel inter- and intrachromosomal chromosome 1 aberrations in follicular lymphomas by using an innovative multicolor banding technique

Follicular lymphoma (FL) is characterized by t(14;18)(q32;q21), which is the initial genetic perturbation in this disease. Additional genetic mutations are required to generate a fully malignant phenotype. Secondary chromosomal alterations seen in FL include prominent involvement of chromosome 1 in the form of balanced or unbalanced translocations, insertions, deletions, and duplications involving both the p and q arms. We investigated a diagnostically well defined set of 55 t(14;18)-positive FL cases with complex karyotypes by means of multicolor karyotyping. Sixteen cases showed involvement of chromosome 1 and were analyzed in further detail by a novel multicolor banding technique for this chromosome. We defined three groups showing varying complexity of chromosome 1 alterations. The first group revealed simple translocations, such as t(1;2), t(1;6), t(1;8), and t(1;17), involving breakpoints on either the p or the q arm of chromosome 1. The second group showed more complex rearrangements with translocations, insertions, regional duplications, and involvement of more than one partner chromosome with either the p or the q arm of chromosome 1. The third group was defined by highly complex rearrangements involving translocations, regional duplications, amplifications, and intrachromosomal band relocations affecting the entire chromosome 1. All three groups shared interchromosomal rearrangements of chromosome 1 with chromosome 8, often involving the MYC protooncogene site, amplification involving region 1q21-q31, and deletion involving region 1p36. Thus, the use of sophisticated multicolor molecular cytogenetic assays in the investigation of malignant lymphoma allows precise characterization of chromosomal alterations and will provide a better understanding of their biology.

Multiple myeloma: evolving genetic events and host interactions

Multiple myeloma is a neoplasm of terminally differentiated B cells (plasma cells) in which chromosome translocations frequently place oncogenes under the control of immunoglobulin enhancers. Unlike most haematopoietic cancers, multiple myeloma often has complex chromosomal abnormalities that are reminiscent of epithelial tumours. What causes full-blown myeloma? And can our molecular understanding of this common haematological malignancy be used to develop effective preventive and treatment strategies?

A novel dic(1;10) in a patient with myelodysplastic syndrome

We report on a case of refractory anemia with trilineage dysplasia and an unbalanced der(1)t(1;10) that resulted in trisomy of the long arm of chromosome 1 (1q) and monosomy of the short arm of chromosome 10 (10p). Fluorescence in situ hybridization showed that the rearranged chromosome contained the centromeres of both chromosomes 1 and 10, leading to a dic(1;10). To our knowledge, a dicentric chromosome involving chromosomes 1 and 10 has never been described in hematological malignancies.

Genome-wide search for loss of heterozygosity in Burkitt lymphoma cell lines

The molecular biological characteristics of Burkitt lymphoma (BL), in addition to the presence of the Epstein-Barr virus (EBV) in some forms, relies on well-characterized alterations, such as MYC translocations and TP53 inactivations. To ascertain the number and location of other genome alterations, we used 191 polymorphic markers in a genome-wide search for loss of heterozygosity (LOH) in 31 Burkitt lymphoma cell lines and their normal counterparts. We were able to distinguish two types of altered allelic patterns: a bona fide LOH profile, indicative of deletion (LOH), and a profile indicative of increased dosage (ID). The former type was most frequent at chromosome arm 17p, most likely indicating TP53 gene inactivation. Increased dosage at 1q was found almost exclusively in non-EBV cell lines (P < 0.00004) and correlated well with karyotypic abnormalities affecting region 1q21-25. Our results suggest that a gene important for BL pathogenesis is located in region 1q21-25 and that the activation of this gene mimics the effects of EBV.

Primary effusion lymphomas exhibit complex and recurrent cytogenetic abnormalities

Cytogenetic findings in a few primary effusion lymphoma (PEL) cell lines have been reported, but only three complete karyotypes of primary specimens from patients with this neoplasm have been published. In this study, cytogenetic analysis was performed on 11 effusion specimens from 10 patients with PEL. We corroborate data obtained from the cell line studies that trisomy 7, trisomy 12 and aberrations in the proximal long arm of chromosome 1 (1q) are recurring cytogenetic aberrations in PEL and also identify breakpoints at 3q23, 7p22, 7q22, 10q24, 12q24, 13q22, 14q24, 14q32, 15p11.2 and Xq22 as well as +8, +15, +19, +X and -Y as recurring chromosome abnormalities. The identification of recurring cytogenetic aberrations may lead to delineation of the genetic events in PEL.

Novel evidence of a role for chromosome 1 pericentric heterochromatin in the pathogenesis of B-cell lymphoma and multiple myeloma

1q rearrangement is a remarkably frequent secondary chromosomal change in both non-Hodgkin's lymphoma (NHL) and multiple myeloma (MM), where it is associated with tumor progression. To gain insight into 1q rearrangement-associated disease mechanisms, we used fluorescence in situ hybridization (FISH) to search for recurring 1q breaks in 35 lymphoma samples (31 NHL patients and 4 lymphoma-derived cell lines) as well as 22 MM patients with cytogenetically determined 1q abnormalities. Strikingly, dual-color FISH analysis with chromosome 1 centromere and 1q12-specific probes identified constitutive heterochromatin band 1q12 as the single most frequent breakpoint site in both NHL and MM (39% and 89% of 1q breaks, respectively). These rearrangements consistently generated aberrant heterochromatin/euchromatin junctions and gain of 1q12 material. A further 30% of NHL 1q breaks specifically involved two other novel, closely spaced sites (clusters I and II) within a 2.5 Mb region of proximal 1q21 (D1S3620 to D1S3623). A possible association between these sites and NHL subtype was evident; the cluster I rearrangement was frequent in follicular and diffuse large cell lymphoma, whereas the cluster II rearrangement was more frequently observed in diffuse small-cell lymphoma (2/2 marginal zone lymphomas, 1/2 atypical chronic lymphocytic leukemias, and 1 lymphoplasmacytic lymphoma in this series). Candidate oncogenes bordering this interval (BCL9 and AF1Q) were not rearranged in any patient except one (AF1Q). This study provides the first evidence of involvement of 1q12 constitutive heterochromatin in the pathogenesis of NHL and MM and indicates proximal 1q21 to be of specific pathological significance in NHL.

Recurrent chromosomal rearrangements involving breakpoints 3p21 and 19q13 in Chinese IgD multiple myeloma detected by G-banding and multicolor spectral karyotyping: a review of IgD karyotype literature

Immunoglobulin D multiple myeloma (IgD MM) is a rare subtype that accounts for 1% to 3% of MM and shows higher aggressiveness with distinctive clinical and laboratory features. However, there is little information in the literature on their karyotypes, which are mainly derived from G-banding results. Our current study on 2 Chinese IgD MM thus represents the first description of cytogenetic data on this subtype based on an integrated analysis with G-banding and multicolor spectral karyotyping (SKY). Both of our cases showed some usual features of MM, as well as a few novel translocations including t(3;22), t(6;19), t(X;19) and the 3 whole-arm translocations namely t(1;6)(q10;p10), t(4;9)(q10;p10), and t(16;18)(q10;q10). We also identified recurrent chromosomal rearrangements involving breakpoints 3p21 and 19q13, which may suggest to be unique aberrations that may underline the pathogenesis of this distinctive biological MM subtype.

Hypomethylation of chromosome 1 heterochromatin DNA correlates with q-arm copy gain in human hepatocellular carcinoma

Using comparative genomic hybridization (CGH) analysis, we, and others, have shown that there is a high and consistent incidence of chromosome 1q copy gain in human hepatocellular carcinoma (HCC). Chromosome 1 rearrangements, that involved peri-centromeric breakpoints, have also been frequently reported in karyotypic studies of HCC. Satellite DNA hypomethylation has been postulated as the mechanism underlying the induction of chromosome 1 peri-centromeric instability in many human cancers and in individuals with the rare recessive disorder ICF (immunodeficiency, centromeric heterochromatin instability, facial anomalies). In this study, we have investigated the role of DNA hypomethylation in 1q copy gain in HCC by examining the methylation status of chromosome 1 heterochromatin DNA (band 1q12). Thirty-six histologically confirmed samples of HCC were studied (24 paired tumor and adjacent nontumorous liver tissues, and 12 tumor only). Hypomethylation of satellite 2 (Sat2) DNA in 1q12 was analyzed by Southern blotting using methyl-sensitive enzyme digestion. In parallel, all cases were analyzed by CGH. A strong correlation between hypomethylated Sat2 sequences and 1q copy gain with a 1q12 breakpoint was found (P < 0.001). We postulate that such hypomethylation alters the interaction between the CpG-rich satellite DNA and chromatin proteins, resulting in heterochromatin decondensation, breakage and aberrant 1q formation. Spectral karyotyping further supported the presence of fragile 1q12 in HCC. Of particular interest was the finding of Sat2 DNA hypomethylation in 5 of 24 adjacent nontumorous liver tissues examined. These tissues showed no evidence of malignancy on histological examination nor did they display any CGH abnormalities. Our findings suggest a role for Sat2 demethylation in the early stages of the stepwise progression of liver carcinogenesis.

Derivative (1;18)(q10;q10): a recurrent and novel unbalanced translocation involving 1q in myeloid disorders

We report two cases of hematological malignancies, comprising a case of myelodysplastic syndrome (MDS) that rapidly evolved into acute myeloid leukemia, and a case of myeloproliferative disorder (MPD), in which der(1;18)(q10;q10) was found as the sole acquired karyotypic abnormality. This observation indicates that the unbalanced translocation is a recurrent aberration in myeloid disorders. To the best of our knowledge, centromeric fusion between long arms of chromosomes 1 and 18, leading to a normal chromosome 18 substituted with a der(1;18) chromosome, is novel and has not been described in cancer. Mechanistically, either trisomy 1q or monosomy 18p that results from the translocation may potentially contribute to leukemogenesis. Finally, chromosomes with large constitutive heterochromatin bands such as chromosome 1 may be at risk of centromeric instability and be predisposed to centromeric fusion with other chromosomes.

Differences in genetic changes between multiple myeloma and plasma cell leukemia demonstrated by comparative genomic hybridization

To analyze the genomic differences between multiple myeloma (MM) and plasma cell leukemia (PCL), a total of 30 cases were studied by comparative genomic hybridization (CGH). In five cases with a low proportion of plasma cells (PC) in bone marrow, an enrichment of PC was performed by using immunomagnetic beads conjugated with the monoclonal antibody B-B4. In 24 out of the 25 MM (96%) and in all five PCL (100%) patients DNA copy number changes were identified by CGH analysis; in the MM case without chromosomal imbalances, the immunomagnetic enrichment of PC had failed. The most recurrent changes in MM patients were gains at chromosomes 15q (48%), 11q (44%), 3q (40%), 9q (40%) and 1q (36%). By contrast, all PCL patients showed gains in 1q. Losses of chromosomal material were significantly more frequent in PCL than in MM patients (P = 0.03): losses on 13q in 80% of PCL vs 28% of MM; and on chromosome 16 in 80% vs 12%, respectively. In addition, PCL patients showed losses of 2q and 6p that were not present in MM. The CGH data show differences in chromosomal imbalances between MM and PCL.

Jumping translocations are common in solid tumor cell lines and result in recurrent fusions of whole chromosome arms

Jumping translocations (JTs) and segmental jumping translocations (SJTs) are unbalanced translocations involving a donor chromosome arm or chromosome segment that has fused to multiple recipient chromosomes. In leukemia, where JTs have been predominantly observed, the donor segment (usually 1q) preferentially fuses to the telomere regions of recipient chromosomes. In this study, spectral karyotyping (SKY) and FISH analysis revealed 188 JTs and SJTs in 10 cell lines derived from carcinomas of the bladder, prostate, breast, cervix, and pancreas. Multiple JTs and SJTs were detected in each cell line and contributed to recurrent unbalanced whole-arm translocations involving chromosome arms 5p, 14q, 15q, 20q, and 21q. Sixty percent (113/188) of JT breakpoints occurred within centromere or pericentromeric regions of the recipient chromosomes, whereas only 12% of the breakpoints were located in the telomere regions. JT breakpoints of both donor and recipient chromosomes coincided with numerous fragile sites as well as viral integration sites for human DNA viruses. The JTs within each tumor cell line promoted clonal progression, leading to the acquisition of extra copies of the donated chromosome segments that often contained oncogenes (MYC, ABL, HER2/NEU, etc.), consequently resulting in tumor-specific genomic imbalances. Published 2001 Wiley-Liss, Inc.

IRTA1 and IRTA2, novel immunoglobulin superfamily receptors expressed in B cells and involved in chromosome 1q21 abnormalities in B cell malignancy

Abnormalities of chromosome 1q21 are common in B cell malignancies, but their target genes are largely unknown. By cloning the breakpoints of a (1;14) (q21;q32) chromosomal translocation in a myeloma cell line, we have identified two novel genes, IRTA1 and IRTA2, encoding cell surface receptors homologous to the Fc and inhibitory receptor families. Both genes are selectively expressed in mature B cells: IRTA1 in marginal zone B cells and IRTA2 in centrocytes, marginal zone B cells, and immunoblasts. As a result of the t(1;14), IRTA1 is fused to the immunoglobulin Calpha domain to produce a chimeric IRTA1/Calpha fusion protein. In tumor cell lines with 1q21 abnormalities, IRTA2 expression is deregulated. Thus, IRTA1 and IRTA2 are novel immunoreceptors implicated in B cell development and lymphomagenesis.

Multicolour spectral karyotyping identifies new translocations and a recurring pathway for chromosome loss in multiple myeloma

Multicolour spectral karyotyping (SKY) was performed on primary tumour specimens from 100 patients with multiple myeloma (MM) that showed complex clonal chromosome aberrations not fully characterized by G-banding. In this study, SKY was able to identify or revise translocations with breakpoints involving 14q32, 11q13 or 8q24 in 32 patients (32%). Five new recurring translocations were identified, two of which involved chromosome 22. A subtle reciprocal translocation t(14;22) (q32;q11 approximately 12) was identified using SKY in two patients and a second, much larger, translocation t(11;22)(q13;q13) was identified using G-banding in three patients. A third new translocation was identified in two patients using SKY and G-banding as der(7)t(7;7)(p15 approximately 22;q22 approximately 32). Twenty-three patients (23%) showed the loss of 8p by whole-arm translocations with different whole-arm donor chromosomes. Among this group, two new recurring whole-arm translocations involving the centromeric breakpoint 8q10 were identified as der(8;20)(q10;q10) and der(8;18) (q10;q10) in three patients each. In addition, a novel pattern of three-way translocations involving the clonal evolution of the t(8;22)(q24;q11) by the subsequent loss of 8p by whole-arm translocations was found in three patients. The chromosome instability identified here demonstrates that the loss of 8p can occur by multiple whole-arm translocations, indicating a new pathway for the loss of a specific chromosome region in MM.

Distal deletion of 1p in colorectal tumors: an initial event and/or a step in carcinogenesis? Study by fluorescence in situ hybridization interphase cytogenetics

Cytogenetics studies have suggested that short arm deletion in chromosome 1 is involved in triggering colorectal tumor development. To elucidate the role of 1p under-representation in the tumoral process, we investigated by fluorescence in situ hybridization interphase cytogenetics, using simultaneously centromeric and p36 telomeric probes for chromosome 1, 27 primary adenocarcinomas, 5 metastases, 5 adenomas and as control 4 normal mucous membranes. The 1p under-representation in paradiploid tumoral cells, interpreted as a 1p deletion, was observed in 8/27 adenocarcinomas, 2/5 metastases and 3/5 adenomas. Thus, in diploid cells 1p deletion was observed in some tumors independently of the stage of the process. The 1p under-representation in total number of examined cells, i.e., diploid and aneuploid, was observed in 14/16 grade B1-B2 tumors, in 5/8 grade C1-C2 tumors, and all grade D tumors (3/3) and all metastases (5/5). There were no correlations with location or histological characteristics of cancers, gender or age of patients. These results show high frequency of 1p under-representation in intestinal tumors, and lead to separate the under-representation of 1p in diploid cells, which correspond to a 1p deletion probably implicated in the initiation of the process, from the under-representation in aneuploid cells, which mainly may be the consequence of complex rearrangements in relation to extension of the malignant process.

A comprehensive karyotypic study on human hepatocellular carcinoma by spectral karyotyping

The current paucity of cytogenetic information on hepatocellular carcinoma (HCC) reflects the difficulties in culturing hepatocytes in vitro. Here, we report on the successful culture of 15 HCC cases. Chromosome aneuploidy ranging from a near-diploid to hyperhexaploid karyotype was found, but their complete karyotypic interpretations were hampered by the presence of many unidentifiable rearrangements. Spectral karyotyping (SKY) was used to elucidate structural changes in these HCC samples and 3 liver cancer cell lines (PLC/PRF/5, Hep3B, and HepG2). Frequent structural abnormalities were found on chromosomes 1 (13 of 15 cases; 3 of 3 cell lines), 8 (10 of 15 cases; 2 of 3 cell lines), 17 (9 of 15 cases; 3 of 3 cell lines), and 19 (9 of 15 cases; 1 of 3 cell lines). In particular, the chromosome regions 1p13-q21, 8p12-q21, 17p11-q12, 17q22, and 19p10-q13.1 were involved in multiple rearrangements. SKY analysis also suggested several previously undescribed breakpoints in HCC. These breakpoints, predominantly pericentromeric, clustered around the chromosome bands 2q33-q34, 3p13-q12, 4p14-q12, 5p10-q11, 7p12-q11, 10q10-q11, 11q10, 11q13-q21, 12q10-q13, 12q22-q23, 13q10-q14, 15q10, 16q10-q13, 18p11-q11, 20p11-q13.1, 21q10, and 22q10. When tumor sizes were compared, a significantly higher number of structural abnormalities was found in tumors larger than 4 cm (P =.007). Rearrangements such as t(1;8), t(1;11), t(1;19), and t(17;21) that were identified in both primary tumors and cell lines might represent markers that reflect proliferative advantages. Although SKY analysis did not indicate consistent translocations, it suggested nonrandom breakpoints, predominantly in the pericentromeric region, on a number of chromosomes. These breakpoint clusters may thus prove to be more important in the liver carcinogenesis and targets for further molecular investigations.

The relationship between spontaneous telomere loss and chromosome instability in a human tumor cell line

Chromosome instability plays an important role in cancer by promoting the alterations in the genome required for tumor cell progression. The loss of telomeres that protect the ends of chromosomes and prevent chromosome fusion has been proposed as one mechanism for chromosome instability in cancer cells, however, there is little direct evidence to support this hypothesis. To investigate the relationship between spontaneous telomere loss and chromosome instability in human cancer cells, clones of the EJ-30 tumor cell line were isolated in which a herpes simplex virus thymidine kinase (HSV-tk) gene was integrated immediately adjacent to a telomere. Selection for HSV-tk-deficient cells with ganciclovir demonstrated a high rate of loss of the end these "marked" chromosomes (10-4 events/cell per generation). DNA sequence and cytogenetic analysis suggests that the loss of function of the HSV-tk gene most often involves telomere loss, sister chromatid fusion, and prolonged periods of chromosome instability. In some HSV-tk-deficient cells, telomeric repeat sequences were added on to the end of the truncated HSV-tk gene at a new location, whereas in others, no telomere was detected on the end of the marked chromosome. These results suggest that spontaneous telomere loss is a mechanism for chromosome instability in human cancer cells.

Trisomy of the long arm of chromosome 1 resulting in a dicentric derivative (6)t(1;6) chromosome in a child with myelodysplastic syndrome following treatment for a primitive neuroectodermal tumor

We report the clinical, hematologic, and cytogenetic findings for a child with secondary myelodysplastic syndrome (MDS) after treatment for a primitive neuroectodermal tumor. At the time of conversion to MDS, conventional cytogenetics revealed an unbalanced der(6)t(1;6) that resulted in trisomy of the long arm of chromosome 1 and partial monosomy and duplication of 6p. Using alpha satellite probes, fluorescence in situ hybridization of bone marrow cells showed that the rearranged chromosome contained the centromeres of both chromosomes 1 and 6, thus forming a dic(1;6) resulting in trisomy 1q. This report is the first to describe a case of childhood secondary myelodysplastic syndrome associated with a trisomy 1q involving chromosome 6.

Identification of a high frequency of chromosomal rearrangements in the centromeric regions of prostate cancer cell lines by sequential giemsa banding and spectral karyotyping

BACKGROUND

Currently, prostate cancer (CaP) cytogenetics is not well defined, largely because of technical difficulties in obtaining primary tumor metaphases.

METHODS AND RESULTS

We examined three CaP cell lines (LNCaP, DU145, PC-3) using sequential Giemsa banding and spectral karyotyping (SKY) to search for a common structural aberration or translocation breakpoint. No consistent rearrangement common to all three cell lines was detected. A clustering of centromeric translocation breakpoints was detected in chromosomes 4, 5, 6, 8, 11, 12, 14, and 15 in DU145 and PC-3. Both these lines were found to have karyotypes with a greater level of complexity than LNCaP.

CONCLUSION

The large number of structural aberrations present in DU145 and PC-3 implicate an underlying chromosomal instability and subsequent accumulation of cytogenetic alterations that confer a selective growth advantage. The high frequency of centromeric rearrangements in these lines indicates a potential role for mitotic irregularities associated with the centromere in CaP tumorigenesis.