Chromosome 11 rearrangements in the different haematological neoplasias

The cases of chromosome 11 abnormalities in leukemic bone marrow cells have constituted 14.0% in acute lymphoblastic leukemia (ALL), 18.7% in acute myeloid leukemia (AML), and 16.7% in refractory anemia (RA). The bands of the short arms 11p13, 11p14, llp15 and the long arms 11q14, 11q21, 11q23 were involved in chromosome rearrangements. The rearrangements of the band 11q23 were detected more often. Reciprocal translocations were found with the highest frequency, while para- and pericentic invertions, terminal and intestitial deletions occured with the lower incidence. Deletions were found in RA cases only. Comparison with the clinical features showed no correlation with the age and the main haematological indexes including the amount of blast cells in the initial period. The results have showed the poor prognosis of the abnormalities not only of 11q21, 11q23 in acute leukemia (AL), but of 11p13, 11p15 in AML as well, while not enough data on this subject is availalbe in the literature.     

Chromosome 11 rearrangements in various hematological neoplasias

Chromosome 11 abnormalities in leukemic bone marrow cells were observed in 14.0% of the cases of acute lymphoblastic leukemia (ALL), in 18.7% of acute myeloid leukemia (AML) cases, and in 16.7% of refractory anemia (RA) cases. Bands 11pl3, 11pl4, 11pl5 on the short arm and 11ql4, 11q21, 11q23 on the long arm of chromosome 11 were involved in these rearrangements. Rearrangements of band 11q23 were detected most often. Reciprocal translocations were found with the highest frequency, while para-and pericentic inversions and deletions, both terminal and interstitial, occurred less often. In RA cases only deletions were observed. Comparison of clinical features showed no correlation with age and major hematological indexes such as the number of blast cells in the initial period. These results show that the prognosis is poor in cases of abnormalities at both 11q21 and 11q23 in acute leukemia (AL) as well as in 11pl3 and 11pl5 in AML. This is the first observation of these phenomena.     

A novel translocation,t(9;21)(q13;q22) rearranging the RUNX1 gene in acute myelomonocytic leukemia

A novel translocation t(9;21)(q13;q22) associated with trisomy 4 has been detected in a patient with acute myelomonocytic leukemia (AML,M4) in relapse. The chromosomal translocation results in rearrangement of the RUNX1 gene at 21q22. The DNA sequence rearranged on chromosome 9 remains unidentified. The diversity of the partners involved in translocations implicating RUNX1 suggests that the functional consequences of the abnormality are more due to the truncation of RUNX1 than to the identity of its partner in the rearrangement.     

Patterns of BCR/ABL Gene Rearrangements in Chronic Myeloid Leukemia with Complex t(9;22) Using Fluorescence In Situ Hybridization (FISH)

Chronic myeloid leukemia (CML) is characterized by the reciprocal translocation t(9;22)(q34;q11.2) which fuses the ABL1 oncogene on chromosome 9 with the BCR gene on chromosome 22. It is the BCR/ABL protein that drives the neoplasm and the ABL/BCR is not necessary for the disease. In the majority of CML cases, the BCR/ABL fusion gene is cytogenetically recognizable as a small derivative chromosome 22(der 22), which is known as the Philadelphia (Ph) chromosome. However, approximately 2-10% of patients with CML involve cryptic or complex variant translocations with deletions on the der(9) and/or der(22) occuring in roughly 10-15% of CML cases. Fluorescence in situ hybridization (FISH) analysis can help identify deletions and complex or cryptic rearrangements. Various BCR/ABL FISH probes are available, which include dual color single fusion, dual color extra signal (ES), dual color dual fusion and tri color dual fusion probes. To test the utility of these probes, six patients diagnosed with CML carrying different complex variant Ph translocations were studied by G-banding and FISH analysis using the BCR/ABL ES, BCR/ABL dual color dual fusion, and BCR/ABL tricolor probes. There are differences among the probes in their ability to detect variant rearrangements, with or without accompanying chromoso me 9 and/or 22 deletions, and low level disease.     

Cytogenetics and molecular genetics of acute lymphoblastic leukemia

An important factor in the diagnosis of acute lymphoblastic leukemia (ALL) is that karyotype is an independent prognostic indicator, with an impact on the choice of treatment. Outcome is related to the number of chromosomes. For example, high hyperdiploidy (51-65 chromosomes) is associated with a good prognosis, whereas patients with near haploidy (23-29 chromosomes) have a poor outcome. The discovery of recurring chromosomal abnormalities in the leukemic blasts of patients with ALL has identified a large number of genes involved in leukemogenesis. Certain specific genetic changes are related to prognosis. The ETV6/AML1 fusion arising from the translocation (t12;21) (p13;q22) has been associated with a good outcome; the BCR/ABL fusion of (t9;22)(q34;q11), rearrangements of the MLL gene, and abnormalities of the short arm of chromosomes 9 involving the tumor suppressor genes p16INK4A have a poor prognosis. Unfortunately, the classification of patients into prognostic groups based on cytogenetics is not always as predicted. Even when other clinically based risk factors are taken into account, some patients with good-risk cytogenetic features will relapse. In the search for new measures of prognosis, it has recently emerged that the level of minimal residual disease following induction therapy can be a reliable predictor of outcome in ALL.     

Loss-of-function mutation of the AF9/MLLT3 gene in a girl with neuromotor development delay, cerebellar ataxia, and epilepsy

The human AF9/MLLT3 gene is a common fusion partner for the MLL gene in translocations t(9;11)(p22;q23) associated with acute myeloid leukemia and acute lymphocytic leukemia. The exact function of the gene is still unknown, although a mouse knock-out model points to a role as a controller of embryo patterning. We report the case of a constitutional translocation t(4;9)(q35;p22) disrupting the AF9/MLLT3 gene in a girl with neuromotor development delay, cerebellar ataxia and epilepsy. Array-CGH analysis at 1 Mbase resolution did not reveal any additional deletions/duplications. We hypothesize a loss-of-function mutation of the AF9/MLLT3 gene, and a possible role for the FAT gene on chromosome 4, in the genesis of the proband’s severe neurological phenotype.     

Chronic myelogenous leukemia with translocations (3q-;9q+) and (17q-;22q+). Possible crucial cytogenetic events in the genesis of CML

Summary Two reciprocal translocations involving chromosomes 3, 9, 17, and 22 were found in a patient with seemingly Ph¹-negative chronic myelogenous leukemia (CML). The two translocations were t(3;9)(q21;q34) and t(17;22)(q21;q11); the breakage in chromosomes 9 and 22 apparently occurred at the same point as in the usual Ph¹ translocation, t(9;22)(q34;q11).From the present evidence and a review of the literature it appears that the breakage on both chromosomes 9 and 22 at the special regions and the separation of the fragments are present in practically all standard and variant Ph¹ translocations, even those in which the terminal region of the long arm of chromosome 9 (9q) does not seem to be involved in the rearrangement; however, a translocation between chromosomes 9 and 22 is not an obligatory result of the rearrangement, as seen in the present case. Thus, we postulate that the breakage on both chromosomes 9 and 22 at the special regions and separation of the fragments are the crucial cytogenetic events in the genesis of CML and stress the importance of paying careful attention to the terminal region of 9q, particularly when chromosome 9 does not seem to be involved in the rearrangement.This work was supported in part by grants (Nos. 401001 and 401071) from the Ministry of Education, Science and Culture of Japan     

Chromatin structural elements and chromosomal translocations in leukemia

Recurring chromosome abnormalities are strongly associated with certain subtypes of leukemia, lymphoma and sarcomas. More recently, their potential involvement in carcinomas, i.e. prostate cancer, has been recognized. They are among the most important factors in determining disease prognosis, and in many cases, identification of these chromosome abnormalities is crucial in selecting appropriate treatment protocols. Chromosome translocations are frequently observed in both de novo and therapy-related acute myeloid leukemia (AML) and myelodysplastic syndromes (MDS). The mechanisms that result in such chromosome translocations in leukemia and other cancers are largely unknown. Genomic breakpoints in all the common chromosome translocations in leukemia, including t(4;11), t(9;11), t(8;21), inv(16), t(15;17), t(12;21), t(1;19) and t(9;22), have been cloned. Genomic breakpoints tend to cluster in certain intronic regions of the relevant genes including MLL, AF4, AF9, AML1, ETO, CBFB, MYHI1, PML, RARA, TEL, E2A, PBX1, BCR and ABL. However, whereas the genomic breakpoints in MLL tend to cluster in the 5' portion of the 8.3 kb breakpoint cluster region (BCR) in de novo and adult patients and in the 3' portion in infant leukemia patients and t-AML patients, those in both the AML1 and ETO genes occur in the same clustered regions in both de novo and t-AML patients. These differences may reflect differences in the mechanisms involved in the formation of the translocations. Specific chromatin structural elements, such as in vivo topoisomerase II (topo II) cleavage sites, DNase I hypersensitive sites and scaffold attachment regions (SARs) have been mapped in the breakpoint regions of the relevant genes. Strong in vivo topo II cleavage sites and DNase I hypersensitive sites often co-localize with each other and also with many of the BCRs in most of these genes, whereas SARs are associated with BCRs in MLL, AF4, AF9, AML1, ETO and ABL, but not in the BCR gene. In addition, the BCRs in MLL, AML1 and ETO have the lowest free energy level for unwinding double strand DNA. Virtually all chromosome translocations in leukemia that have been analyzed to date show no consistent homologous sequences at the breakpoints, whereas a strong non-homologous end joining (NHEJ) repair signature exists at all of these chromosome translocation breakpoint junctions; this includes small deletions and duplications in each breakpoint, and micro-homologies and non-template insertions at genomic junctions of each chromosome translocation. Surprisingly, the size of these deletions and duplications in the same translocation is much larger in de novo leukemia than in therapy-related leukemia. We propose a non-homologous chromosome recombination model as one of the mechanisms that results in chromosome translocations in leukemia. The topo II cleavage sites at open chromatin regions (DNase I hypersensitive sites), SARs or the regions with low energy level are vulnerable to certain genotoxic or other agents and become the initial breakage sites, which are followed by an excision end joining repair process.     

Phenomenon of evolution of clonal chromosomal abnormalities in childhood acute myeloid leukemia

An analysis of chromosomal abnormalities in bone-marrow cells was performed in 116 children with diagnoses of acute myeloid leukemia (AML). The frequency of the evolution of clonal chromosomal abnormalities in AML constituted 42.3%. Quantitative abnormalities of chromosomes 8, 9, and 21, as well as the secondary structural abnormalities in the chromosomal regions 12p12, 9p22, 9q22, 9q34, 11q14–23, and 6q2, were the most abundant. Quantitative abnormalities were registered in 26.7% cases. The basic mechanism of evolution of the leukemic clone contained trisomy, deletions, and monosomy. The frequency of evolution was seven times higher in the age group of up to 2 years and twofold higher in the age group of up to 5 years. The high frequency of evolution at t(15;17)(q22;q22) was established, while its absence was revealed at inv(16)(p13q22). Patients with clonal evolution were characterized by the increased frequency of relapses and earlier death before reaching remission, which might be explained by the severe initial state of those patients. The conception of abnormalities in the evolution of the clone was proposed to occur at certain stages as follows: (1) appearance of balanced rearrangements; (2) trisomy occurrence; (3) loss of chromosomal material. The occurrence of an unbalanced genome during evolution possesses advantages in the clonal proliferate activity and may be related to its response to chemotherapy. An identity in abnormal chromosomal structure was revealed as a result of the comparison of karyotypes during diagnostics and during relapse, which could be evidence of the initial induction of some types of evolution of chromosomal abnormalities in leukemic cells in AML children by the chemical agents.     

A Palindrome-Mediated Recurrent Translocation with 3:1 Meiotic Nondisjunction: The t(8;22)(q24.13;q11.21)

Palindrome-mediated genomic instability has been associated with chromosomal translocations, including the recurrent t(11;22)(q23;q11). We report a syndrome characterized by extremity anomalies, mild dysmorphia, and intellectual impairment caused by 3:1 meiotic segregation of a previously unrecognized recurrent palindrome-mediated rearrangement, the t(8;22)(q24.13;q11.21). There are at least ten prior reports of this translocation, and nearly identical PATRR8 and PATRR22 breakpoints were validated in several of these published cases. PCR analysis of sperm DNA from healthy males indicates that the t(8;22) arises de novo during gametogenesis in some, but not all, individuals. Furthermore, demonstration that de novo PATRR8-to-PATRR11 translocations occur in sperm suggests that palindrome-mediated translocation is a universal mechanism producing chromosomal rearrangements.     

Ring chromosome 8 and translocation t(8;21) in a patient with acute myeloblastic leukemia

Recurrent translocation t(8;21)(q22;q22) acute myeloid leukemia (AML) is often associated with secondary chromosome changes of which the clinical significance is not clear since they do not seem to impair the prognosis. Uncommon chromosome changes may lead to the identification of leukemogenetic factors associated with t(8;21) since the AML1/RUNX1-ETO fusion gene resulting from the translocation is thought to be unable alone to induce leukemia. We here report a patient with AML, t(8;21) and ring chromosome 8 resulting in partial chromosome 8 deletion. Another patient with partial 8q deletion has been previously reported. It is suggested that more attention be paid to the genes located in distal 8q in relation to leukemogenesis.     

ABL/BCR gene variant with two-step mechanism: Unusual localization and rare/novel chromosomal rearrangements in CML patients

Aims: Variant translocations involving 9q, 22q and at least one additional genomic locus occur in 5-10% of the patients with chronic myeloid leukemia (CML). The mechanisms for the formation of these variant translocations are not fully characterized. Here we report CML cases presenting a variant translocation indicating two-step mechanism with rare/novel chromosomal rearrangement. Methods: Karyotype analysis was performed on metaphases obtained through short-term cultures of bone marrow and blood. Detection of BCR-ABL fusion gene was performed using dual-color dual-fusion (D-FISH) and extra signal (ES) translocation probes. BAC-FISH was also carried out. Results: In Patient 1, the third partner chromosome was der(11)(p15) with a 2F2G1R signal pattern, which is an unusual signal pattern with the two-step mechanism. Patients 2 and 3 showed typical positive (2F1G1R) signal pattern. In Patient 2, both the chromosome 22s were involved in variant formation. The second fusion was observed below the BCR gene of the second homologue. In Patient 3 the third chromosome was der(13)(q14). The fourth patient showed a variant pattern with BCR/ABL-ES probe involving der(X)(q13) region. Conclusion: The presence of different rearrangements of both 9q34 and 22q11 regions highlights the genetic heterogeneity of this subgroup of CML. In each case with variants, further studies with FISH, BAC-FISH or more advanced technique such as microarray should be performed. Future studies should be performed to confirm the presence of true breakpoint hot spots and assess their implications in CML with variant Ph.     

Novel chromosomal translocation (17;22)(q12;q12) in a case of myelodisplastic syndrome characterized with signs of hemolytic anemia at presentation

Myelodysplastic syndromes (MDS) are clonal stem cell diseases that can result in cytopenias, dysplasia in one or more cell lineages, infective hematopoiesis, and increase the risk of progression to acute myeloid leukemia (AML). MDSs are characterized by several recurrent cytogenetic defects, which can affect diagnosis, prognosis, and treatment. Some of that chromosomal alterations are associated with very poor prognosis. Conventional cytogenetics cannot accurately define the rearranged karyotype. Instead, molecular cytogenetics analyses can provide important diagnostic and prognostic information for patients affected by MDS, allowing the characterization of the whole mutational spectrum and, mainly, novel chromosomal lesions.In this paper, we report a MDS case with a novel chromosomal translocation [t(17;22)(q12;q22)], described for the first time here. Following Giemsa-banding karyotyping, fluorescent in situ hybridization analyses, by using chromosome-specific probes, displayed the breakpoint regions at chromosomes 17 and 22, within which intra and inter-chromosomal segmental duplications (SD) are present. Because of the occurrence of SDs in breakpoint region, it was not possible to finely define the genomic regions where breaks fell. Further investigations could be required to better understand the molecular basis of the novel translocation t(17;22)(q12;q12) acting in MDS context and to explain if SDs could contribute to the pathogenesis of MDS.     

c-Src activation through a TrkA and c-Src interaction is essential for cell proliferation and hematological malignancies

Although the kinase receptor TrkA may play an important role in acute myeloid leukemia (AML), its involvement in other types of leukemia has not been reported. Furthermore, how it contributes to leukemogenesis is unknown. Here, we describe a molecular network that is important for TrkA function in leukemogenesis. We found that TrkA is frequently overexpressed in other types of leukemia such as acute lymphoblastic leukemia (ALL), chronic myelogenous leukemia (CML), and myelodysplastic syndrome (MDS) including AML. In addition, TrkA was overexpressed in patients with MDS or secondary AML evolving from MDS. TrkA induced significant hematological malignancies by inducing PLK-1 and Twist-1, and enhanced survival and proliferation of leukemia, which was correlated with activation of the phosphatidylinositol 3-kinase/Akt/mTOR pathway. Moreover, endogenous TrkA associated with c-Src complexes was detected in leukemia. Suppression of c-Src activation by TrkA resulted in markedly decreased expression of PLK-1 and Twist-1 via suppressed activation of Akt/mTOR cascades. These data suggest that TrkA plays a key role in leukemogenesis and reveal an unexpected physiological role for TrkA in the pathogenesis of leukemia. These data have important implications for understanding various hematological malignancies.     

Linkage mapping of the AML1 gene on human chromosome 21 using a DNA polymorphism in the 3' untranslated region.

We have detected a polymorphism in the 3' untranslated region of the AML1 gene, which is located at the breakpoint on chromosome 21 in the t(8;21)(q22;q22.3) translocation often associated with patients with acute myeloid leukemia. Informative CEPH families were genotyped for this polymorphism and used to localize the gene on the linkage map of human chromosome 21. The AML1 gene is located between the markers D21S216 and D21S211, in chromosomal band 21q22.3.