Ken Kawakubo

Telomere dynamics in myelodysplastic syndromes and acute leukemic transformation.

Myelodysplastic syndromes (MDS) are characterized by cytopenias in the blood and dysplastic features in the hematopoietic cells. Although the impact of cytogenetic abnormalities is considerable for prognosis, the exact genetic mechanism of MDS remains undetermined. In this study we assessed cytogenetic changes, microsatellite alterations, and telomere dynamics in order to obtain further insight into the pathogenesis of MDS. Thirty-three percentage of MDS patients and 60% of post-MDS acute leukemia (post-MDS AML) had de novo microsatellite changes. In the MDS phase, however, > 60% of patients showed reduction of telomere lengths without microsatellite changes, indicating that telomere reduction in most MDS patients does not seem to be directly linked to genome instability, or that reduction of telomere length does not induce microsatellite changes in the MDS phase. Some MDS patients had microsatellite changes without telomerase elevation, indicating that genome instability might accumulate during the disease progression in some MDS patients, and this condition (cellular senescence) may be related to ineffective hemopoiesis in MDS patients. In contrast, 40% of post-MDS AML patients had elevated telomerase activity with microsatellite changes, indicating that approximately 40% of patients with post-MDS AML patients had accumulation of genome instability resulting in elevated telomerase activity in an attempt to obtain genetic stability. However, the remaining MDS patients had microsatellite changes without telomerase up-regulation, suggesting that some MDS had genome instability even after leukemic transformation. Most MDS patients with elevated telomerase activity in the AML phase had elevated telomerase activity even in the MDS phase without apparent change in telomere length before and after leukemic transformation. These findings indicate that telomerase activity in the MDS phase may be independent of telomere length, although telomere shortening seems to be related to genomic instability, and this process may be linked to apoptosis of MDS cells.

Telomere Dynamics and Genetic Instability in Disease Progression of Chronic Myeloid Leukemia

Chronic myeloid leukemia (CML) is characterized by a Philadelphia (Ph) translocation creating a novel BCR-ABL oncoprotein, and CML patients have a chronic phase for several years followed by an intractable blast cell proliferation, called blast transformation. In the blast phase, more than 60% of patients show additional cytogenetic changes, e. g., double Ph, +8, i(17q). In this review, we would like to address genetic changes, including genome instability, cytogenetic changes, and telomere dynamics that relate to karyotypic instability. In the chronic phase, approximately 60% of CML patients show reduced telomere length without highly elevated telomerase activity or microsatellite alterations, indicating that telomere reduction may be linked to cell replication. Therefore, the Ph translocation might be a first event to immortalize cell proliferation. In the blast phase, 50% of CML patients have high levels of elevated telomerase activity and the same number of patients had microsatellite changes. Of note is that most patients with telomerase up-regulation in the blast phase had additional cytogenetic changes and >60% of them showed microsatellite changes at least at one locus. In contrast, most patients without telomerase activity did not show microsatellite changes. These findings may indicate that telomerase up-regulation in the blast phase of CML patients is closely associated with microsatellite changes (representative of genome instability), while blast cells in the remaining patients (30%) maintain their proliferative capability without microsatellite changes and telomerase up-regulation. This further suggests that there is also an unknown mechanism for genome stability without the process of telomerase up-regulation in some patients with CML in blast crisis.

Clinical and biologic characteristics of CD7+ acute myeloid leukemia: Our experience and literature review

Six patients with acute myeloid leukemia (AML) expressing CD7 antigen (CD7+ AML) were studied. They consisted of five patients with M1 and one with an M2 morphology. Two cases expressed other lymphoid-associated antigens, in addition to CD7. The complete remission rate was 50%. One patient had central nervous system recurrence. Cytogenetic analysis demonstrated normal karyotypes in all the cases. All but one had germline configurations of the T-cell receptor (TCR) genes and immunoglobulin heavy chain gene. However, all did not have detectable recombinase activating gene-1 activity by the RT-PCR technique. We performed colony formation assay in two patients, and no enhancement of colony formation by granulocyte colony-stimulating factor was noted. The results presented here, together with those reported previously, suggest that CD7+ AML may demonstrate lineage infidelity.

Two additional cases of acute myeloid leukemia with t(7;11)(p15;p15) having low neutrophil alkaline phosphatase scores.

We report two additional patients with acute myeloid leukemia (AML) and a translocation between chromosomes 7 and 11: t(7;11)(p15;p15). One patient was diagnosed as having AML-M2 and the other as AML with myelofibrosis. Both patients had low-level neutrophil alkaline phosphatase (NAP) scores. In the literature, only 15 AML patients with t(7;11)(p15;p15) have been reported; nine of them had an AML-M2 morphology, and all had a decreased NAP score. Moreover, mean survival of the reported AML patients with t(7;11)(p15;p15) was 15 months, although 85% of them obtained complete remission, indicating that this type of leukemia frequently tends to relapse. These findings indicate a strong association between the chromosome abnormality and hematologic manifestations of this disease.

Thrombocytopenia induced by imatinib mesylate (Glivec) in patients with chronic myelogenous leukemia: is 400 mg daily of imatinib mesylate an optimal starting dose for Japanese patients?

Imatinib mesylate (Glivec) is a potent and selective inhibitor of the tyrosine kinase activity of BCR-ABL. Because the mechanism of action of imatinib mesylate is inhibition of BCR-ABL tyrosine kinase, it seems likely that to achieve maximum therapeutic benefit for chronic myelogenous leukemia (CML), imatinib mesylate must be administered at a dose that maximally inhibits BCR-ABL kinase activity or, alternatively, that inhibits sufficient BCR-ABL kinase activity to induce apoptosis. According to in vitro study results, 1 M levels of imatinib mesylate are optimal for inducing cell death, and 1 M trough levels are achieved in patients using imatinib mesylate at a daily dose of more than 300 mg [1]. In a phase I/II study in which the dose-response curve in chronic-phase CML patients was examined, the therapeutic effect was reported to plateau at a dose at or slightly above 300 mg. In addition, there was no convincing evidence of dose-limiting toxicity in patients receiving a maximum dose of 1000 mg [2]. These data were used to set the standard therapeutic dose of imatinib mesylate for chronicphase patients at 400 mg daily, and thereafter, the therapeutic benefits for CML patients of imatinib mesylate at this dose were demonstrated in clinical trials [2,3]. This standard therapeutic dose has been used in administering imatinib mesylate to Japanese patients as well as patients in the United States and Europe. At our institute, however, a series of CML patients treated with 400 mg of imatinib mesylate showed thrombocytopenia, and imatinib mesylate adminisThrombocytopenia Induced by Imatinib Mesylate (Glivec) in Patients with Chronic Myelogenous Leukemia: Is 400 mg Daily of Imatinib Mesylate an Optimal Starting Dose for Japanese Patients?

Double-minute chromosomes appearing in a patient with myelodysplastic syndrome with disease evolution.

We present the first case of a myelodysplastic syndrome (MDS) demonstrating an association between the appearance of double-minute chromosomes (dmin) and disease progression. This 59-year-old Japanese woman showed a deletion of the long arm of chromosome 5 [del(5)(q21q34)] and monosomy 9, when she was diagnosed as having refractory anemia with an excess of blasts (RAEB). Subsequential cytogenetic analyses demonstrated that the neoplastic cells in the peripheral blood had six copies of dmin, when the disease progressed into RAEB in transformation (RAEBt). This cytogenetic change was consistently observed when the patient developed the leukemia phase. The findings in this case suggest that the appearance of dmin may be linked to progression of the disease.

Hypomethylated status, but not RAG-1, is required for T-cell receptor-β-chain gene rearrangement in acute leukemia cells

We studied the relation between the level of recombinase activating gene (RAG-1) and the methylation status of T-cell receptor (TCR)-beta-chain gene in TCR-beta rearrangement in acute leukemias, including 21 patients with B-precursor acute lymphoblastic leukemia (ALL) and 23 with acute myeloid leukemia (AML). The rearrangement of the TCR beta-chain gene in acute leukemia always occurs at the allele that contains hypomethylated cytosine-cytosine- guanine-guanine (CCGG) sequences within either the TCR-J beta 1 or TCR-J beta 2 regions. Moreover, all B-precursor ALL patients with TCR-beta rearrangement had hypomethylated TCR-beta with or without the presence of RAG-1 activity detectable by reverse transcript-polymerase chain reaction, whereas none of the AML patients with TCR-beta rearrangement and hypomethylated TCR-beta had detectable RAG-1 activity. Some ALL patients had hypomethylated TCR-beta and RAG-1 activity without TCR-beta rearrangement, and most of them showed t(4;11)(q21;q23) or t(9;22)(q34;q11). These results indicate a correlation between the hypomethylation status of the TCR-beta and its rearrangements, but some unknown blockage factor for this association exists in B-precursor ALL patients with specific chromosomal translocations.

Cytogenetic and immunogenotypic alterations of blast crisis cells in chronic myelogenous leukemia independently linked to immunophenotypic expression

Chronic myelogenous leukemia (CML) is a disease of the hematopoietic stem cells, which can differentiate into either B-lymphoid or myeloid cells, because most of them develop either lymphoid or myeloid blast crisis. Immunophenotypic, genotypic, and cytogenetic analyses of 22 patients (24 episodes) with Philadelphia (Ph) positive CML in blast crisis were performed to determine the genetic alterations of the blast crisis cells. In B-lymphoid blast crisis, all the five patients had immunoglobulin heavy-chain (IgH) rearrangements and most of them showed normal karyotypes. Among the five patients, T-cell receptor (TCR) genes were rearranged at the following occurrence rates: 20% in TCR-beta, 60% in TCR-gamma, and 40% in TCR-delta chain genes. A high incidence of additional chromosome changes was noted in patients with B-lymphoid/myeloid-mixed blast crisis, but about 80% of them had rearranged IgH and about 40% had TCR rearrangements. In contrast, most of the patients with non-lymphoid blast crisis showed further chromosomal abnormalities, including +8, +19, i(17q), and double Ph, and most of them had germline configurations of IgH and TCR-gamma chain genes. Notably, only one patient (dual lymphoid and myelomegakaryoblast crisis) in this group exhibited IgH rearrangement, and TCR-beta and TCR-delta rearrangements were also rarely noted. Rearrangement of the IgH gene in CML blast crisis might be linked to expression of lymphoid markers, especially CD19.

Restoration of cytogenetically normal marrow cells after remission of lymphoblastic crisis in a case of Ph positive CML treated with α-interferon

A patient with Philadelphia (Ph) chromosome-positive chronic myelogenous leukemia (CML) who was treated with alpha-interferon (alpha-IFN) is reported. After the treatment, the number of Ph+ bone marrow (BM) cells decreased gradually and the intensity of the rearranged major breakpoint cluster region (M-BCR) gene became faint; however, a lymphoblastic crisis developed about 1 year later. At the time of the blast crisis, the rearranged M-BCR band was detected, indicating that the blast crisis clone was derived from CML cells. The patient was treated with a combination of vincristine, prednisolone, daunorubicin, and L-asparaginase, and a hematologic remission was obtained. During the remission status, no rearranged M-BCR fragment was detected by conventional Southern analysis. Thus, the hematologic and genetic alteration in this case appeared to be identical to Ph+ acute leukemia with M-BCR rearrangement. The current case therefore indicates that alpha-IFN can reduce the proportion of Ph+ cells, but is unable to prevent blast crisis. Furthermore, the quantitative reduction of the cell population with a Ph chromosome may have some effects in modifying the genetic manifestations and clinical features of Ph+ CML, e.g., the delay in the appearance of the blast crisis.

Multiple myeloma with monosomy 13 developed in trisomy 13 acute myelocytic leukemia: numerical chromosome abnormality during chromosomal segregation process

We report here an acute myelocytic leukemia (AML-M2) patient with trisomy 13 as the sole cytogenetic anomaly, who had relapse of AML with a normal karyotype and developed multiple myeloma. Fluorescence in situ hybridization analysis using the RB gene probe revealed the plasma cells of multiple myeloma (MM) to have monosomy 13 anomaly, whereas relapsed blast cells of AML carried disomy of chromosome 13. To our knowledge, this is the first case showing clonal evolution of trisomy 13 AML and monosomy 13 MM, which might be derived from the leukemic clone at relapse.