Teruaki Hongo

Tandem duplication of the FLT3 gene is found in acute lymphoblastic leukaemia as well as acute myeloid leukaemia but not in myelodysplastic syndrome or juvenile chronic myelogenous leukaemia in children

We examined mRNA expression and internal tandem duplication of the Fms‐like tyrosine kinase 3 (FLT3) gene in haematological malignancies by reverse transcriptase‐polymerase chain reaction (RT‐PCR) and genomic PCR followed by sequencing. By RT‐PCR, expression of FLT3 was detected in 45/74 (61%) leukaemia cell lines and the frequency of expression of FLT3 was significantly higher in undifferentiated type (B‐precursor acute lymphoblastic leukaemia; ALL) than in differentiated type cell lines (B‐ALL) (P = 0.0076). Using the genomic PCR method, 194 fresh samples including 87 acute myeloid leukaemias, 60 ALLs, 32 myelodysplastic syndromes (MDSs) and 15 juvenile chronic myelogenous leukaemias (JCMLs) were examined. Tandem duplication was found in 12 (13.8%) AMLs and two (3.3%) ALLs. Sequence analyses of the 14 samples with the duplication revealed that eight showed a simple tandem duplication and six a tandem duplication with insertion. Most of these tandem duplications occurred within exon 11, and two duplications occurred from exon 11 to intron 11 and exon 12. No tandem duplications of FLT3 gene were detected in MDS or JCML. The frequency of tandem duplication of FLT3 gene in childhood AML was lower than that in adult AML so far reported. All of the 12 AML patients with the duplication died within 47 months after diagnosis, whereas two ALL patients with the duplication have survived 44 and 72 months, respectively. These two ALL patients expressed both lymphoid and myeloid antigens and were considered to have biphenotypic leukaemia. These results suggest that tandem duplication is involved in ALL in addition to AML, but not in childhood MDS or JCML, and that childhood AML patients with the tandem duplication have a poor prognosis.

Alterations of the p53, p21, p16, p15 and RAS genes in childhood T-cell acute lymphoblastic leukemia

We investigated the alterations of the p53, p21, p16, p15 and RAS genes in childhood T-cell acute lymphoblastic leukemia (T-ALL) and T-ALL cell lines by polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP) analysis and direct sequencing. Mutations of the p53 gene were found in three of 57 (5%) patients at diagnosis, one of 14 (7%) patients at relapse and in 12 of 18 (67%) cell lines. In these 12 cell lines, four had more than two mutations of the p53 gene. The p53 mutations were found in four of five cell lines whose original fresh leukemic cells were simultaneously examined original fresh leukemic cells. However, only one of the four fresh leukemic cells had the same mutation. All patients with p53 mutations in the course of disease died. Mutations of the p21 gene were not identified in 71 fresh samples and in 18 cell lines. N-RAS mutations were found in two of 57 (4%) fresh T-ALL patients at diagnosis, and four of 18 cell lines (22%), whereas no mutations were detected in any samples at relapse. Alterations of the p16 gene were found in 18 of 47 (38%) patients at diagnosis and in seven of 14 (50%) at relapse. These differences were not statistically significant. There were no differences in the frequency of alteration of the p16 and p15 genes between event-free patients and the remaining patients. Furthermore, we found the methylation of p16 gene in three of seven patients lacking homozygous deletions, suggesting higher frequency of p16 inactivation than previous reports in T-ALL. Interestingly, we found that one allele is inactivated by methylation and another allele had nonsense mutation in one cell line (KOPT-KI), resulting in loss of protein expression of p16. This type of p16 inactivation has not been so far reported in leukemia. We conclude that, (1) p53 mutations are infrequent at diagnosis but tend to be associated with poor clinical outcome; (2) RAS and p21 mutations may not be involved in the pathogenesis of T-ALL; (3) not only frequent alterations of p16 and p15 genes but also methylation of p16 gene are involved in initiating the leukemogenesis of T-ALLs, and (4) these 5 genes are independently involved in T-ALL.

An in vitro chemosensitivity test for the screening of anti‐cancer drugs in childhood leukemia

We applied the MTT dye reduction assay to the anti‐cancer drug sensitivity test using short‐term microplate cultures. Blast cells were cultured with approximately 25 anti‐cancer drugs for 4 days. After cultivation, MTT dye was placed in each well, and the formazans generated by living cells were dissolved in acidified isopropyl alcohol. The absorbance of each well was measured at a scanning microplate photometer. When we made the table of the cytotoxicity index (CI) that was classified into anti‐cancer drugs and concentrations for each leukemic sample, it was possible to compare efficacy with different drugs and to select the effective ones. Retrospectively, the in vitro results were compared with the clinical responses of the 34 patients (26 of acute lymphocytic leukemia [ALL] and eight of acute nonlymphoblastic leukemia [ANLL]) who were treated by combination chemotherapy. The following results were obtained: true‐positive rate, 78.1%; true‐negative rate, 57.1%; and predictive accuracy, 74.4%. Therefore, the MTT assay‐CI table might serve as a reliable tool for the selection of effective chemotherapy in patients with acute leukemia.

Analysis of the circumstances at the end of life in children with cancer: Symptoms, suffering and acceptance

Abstract Background : In an effort to improve the quality of life of children with cancer, this study analyzes the signs and symptoms at the end of life in such children. It is hoped that these data will contribute to the development of appropriate programs to address the challenges faced by these children.

Mutations of the PTPN11 and RAS genes in rhabdomyosarcoma and pediatric hematological malignancies

PTPN11 has been identified as a causative gene in Noonan syndrome (NS), responsible for about 50% of cases of NS. Given the association between NS and an increased risk of some malignancies, notably leukemia and probably some solid tumors including neuroblastoma (NB) and rhabdomyosarcoma (RMS), recent studies have reported that gain‐of‐function somatic mutations in PTPN11 occur in some hematological malignancies, especially de novo juvenile myelomonocytic leukemia (JMML) and in some solid tumors such as NB, although at a low frequency. In a screen for mutations of PTPN11 in 7 cell lines and 30 fresh tumors of RMS and in 25 cell lines and 40 fresh tumors of NB, we identified a missense mutation (A72T) in an embryonal RMS patient. In the RMS samples, we also detected mutations of NRAS in 1 cell line and 1 patient; both mutations were in embryonal RMSs and had no PTPN11 mutations. No mutations of PTPN11 were detected in NB. In 95 leukemia cell lines and 261 fresh leukemia samples including 22 JMMLs, 9 kinds of missense mutations were detected in 17 leukemia samples, which included 11 (50.0%) mutations in JMML samples and lower frequencies in other hematological malignancies. Furthermore, we identified 4 (18.2%) NRAS mutations and 1 (4.5%) KRAS mutation in 5 JMML samples, 1 of which had a concomitant PTPN11 mutation. Our data suggest that mutations of PTPN11 as well as RAS play a role in the pathogenesis of not only myeloid hematological malignancies but also a subset of RMS malignancies.

AML1/RUNX1 mutations are infrequent, but related to AML-M0, acquired trisomy 21, and leukemic transformation in pediatric hematologic malignancies.

AML1/RUNX1, located on chromosome band 21q22, is one of the most important hematopoietic transcription factors. AML1 is frequently affected in leukemia and myelodysplastic syndrome with 21q22 translocations. Recently, AML1 mutations were found in adult hematologic malignancies, especially acute myeloid leukemia (AML)–M0 or leukemia with acquired trisomy 21, and familial platelet disorder with a predisposition toward AML. Through the use of polymerase chain reaction–single‐strand conformation polymorphism analysis, we examined the AML1 gene for mutations in 241 patients with pediatric hematologic malignancies, and we detected AML1 mutations in seven patients (2.9%). Deletion was found in one patient, and point mutations in four patients, including three missense mutations, two silent mutations, and one mutation within an intron resulting in an abnormal splice acceptor site. All of the mutations except for one were heterozygous. Mutations within the runt domain were found in six of seven patients. Six of seven patients with AML1 mutations were diagnosed with AML, and one had acute lymphoblastic leukemia. In three of these seven patients, AML evolved from other hematologic disorders. AML1 mutations were found in two of four AML‐M0 and two of three patients with acquired trisomy 21. Patients with AML1 mutations tended to be older children. Three of four patients with AML1 mutations who received stem cell transplantation (SCT) are alive, whereas the remaining three patients with mutations without SCT died. These results suggest that AML1 mutations in pediatric hematologic malignancies are infrequent, but are possibly related to AML‐M0, acquired trisomy 21, and leukemic transformation. These patients may have a poor clinical outcome.

Cell culture of small round cell tumor originating in the thoracopulmonary region. Evidence for derivation from a primitive pluripotent cell

The authors describe a 14‐year‐old girl with small round cell tumor originating in the chest wall analyzed by the extensive studies including light and electron microscopic examination, histochemical study, immunochemical study, cytogenetics, and gene analysis. A cell line producing carcinoembryonic antigen (CEA) and neuron‐specific enolase (NSE) has been established from pleural effusion of the pulmonary metastatic tumor. Cytogenetic analysis disclosed a reciprocal translocation (11;22)(q24;q12). Additionally, immunocytochemical studies demonstrated that CEA, NSE, vimentin, cytokeratin, and epithelial membrane antigens are positive, but desmin and S‐100 protein are negative. Although neurofilament was negative in the pulmonary metastatic tumor cells, it became positive in cell line in vitro. These results suggest that this tumor may be derived from the primitive and pluripotential cells, differentiating into mesenchymal, epithelial, and neural features in variable proportions.

Clinical relevance of in vitro chemoresistance in childhood acute myeloid leukemia

To determine the clinical relevance of in vitro drug chemoresistance in childhood acute myeloid leukemia, we used an MTT assay to test leukemic cells from 132 newly diagnosed children. Patients were diagnosed according to the French–American–British (FAB) classification as follows: M0 (n = 12), M1 (n = 16), M2 (n = 53), M4 (n = 17), M5 (n = 19) and M7 (n = 15). The results revealed that, compared to leukemic cells from complete-responders (n = 107), those from non-responders who failed induction therapy (n = 17) were 1.4 to 5.0 times more resistant in vitro to cytarabine (P = 0.005), melphalan (P = 0.003), etoposide (P = 0.011), L-asparaginase (P = 0.017), aclarubicin (P = 0.026) and dexamethasone (P = 0.039). For seven other drugs tested, the median lethal dose of 70% and leukemic cell survival of non-responders were higher than those of complete-responders, but the difference was not statistically significant. We sought correlations between FAB subtypes and in vitro drug resistance. Leukemias of the FAB M4 and M5 subtype were more sensitive to L-asparaginase (P = 0.01, P = 0.0036) than those of the FAB M2 subtype. FAB M5 leukemia was more sensitive to etoposide than were the FAB M2, M4 and M7 subtypes (P = 0.001, P = 0.034, P = 0.023, respectively). By contrast, FAB M5 leukemia was significantly more resistant to prednisolone and dexamethasone than were the FAB M0, M1, M2, M4 and M7 subtypes. We sought correlations between in vitro drug resistance and long-term clinical outcome, but found no associations in this case. These results suggest that in vitro resistance to cytarabine, melphalan, etoposide, L-asparaginase, aclarubicin and dexamethasone might represent factors that can predict response to the early course of therapy. Selecting an appropriate anti-cancer drug according to the FAB classification together with drug sensitivity testing may contribute to improved prognoses in childhood acute myeloid leukemia.

Coduplication of the MLL and FLT3 genes in patients with acute myeloid leukemia

Tandem duplication (TD) of the MLL or FLT3 gene in acute myeloid leukemia (AML) has been reported. We examined whether TD of these two genes occurs simultaneously. We analyzed 13 AML and 2 myelodysplastic syndrome patients, including 6 adult patients with trisomy 11 and 9 pediatric patients with TD of the FLT3 gene, using RT‐PCR followed by sequencing. Among these, TD of the MLL and FLT3 genes was found in 5 and 10 patients, respectively. Notably, TD of both the MLL and FLT3 genes (coduplication) was detected in two AML patients, who died 6 and 14 months after diagnosis. TD of these two genes in AML is rare; thus, coduplication of these genes in the same patient is predicted to be very rare. Although the mechanisms of TD of both genes are different, development of TD of both genes may be related to an unknown similar etiology in leukemia because the frequency of coduplication of these genes in a single patient is considered to be very low. Further studies of the coduplication of these genes in AML patients may lead to the clarification of its mechanism and clinical implications.

Mutations in the ribosomal protein genes in Japanese patients with Diamond-Blackfan anemia

Background Diamond-Blackfan anemia is a rare, clinically heterogeneous, congenital red cell aplasia: 40% of patients have congenital abnormalities. Recent studies have shown that in western countries, the disease is associated with heterozygous mutations in the ribosomal protein (RP) genes in about 50% of patients. There have been no studies to determine the incidence of these mutations in Asian patients with Diamond-Blackfan anemia. Design and Methods We screened 49 Japanese patients with Diamond-Blackfan anemia (45 probands) for mutations in the six known genes associated with Diamond-Blackfan anemia: RPS19, RPS24, RPS17, RPL5, RPL11, and RPL35A. RPS14 was also examined due to its implied involvement in 5q- syndrome. Results Mutations in RPS19, RPL5, RPL11 and RPS17 were identified in five, four, two and one of the probands, respectively. In total, 12 (27%) of the Japanese Diamond-Blackfan anemia patients had mutations in ribosomal protein genes. No mutations were detected in RPS14, RPS24 or RPL35A. All patients with RPS19 and RPL5 mutations had physical abnormalities. Remarkably, cleft palate was seen in two patients with RPL5 mutations, and thumb anomalies were seen in six patients with an RPS19 or RPL5 mutation. In contrast, a small-for-date phenotype was seen in five patients without an RPL5 mutation. Conclusions We observed a slightly lower frequency of mutations in the ribosomal protein genes in patients with Diamond-Blackfan anemia compared to the frequency reported in western countries. Genotype-phenotype data suggest an association between anomalies and RPS19 mutations, and a negative association between small-for-date phenotype and RPL5 mutations.