UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

There is a large increase in lymphoid malignancy in A-T patients and a total absence of myeloid tumors. Penetrance of the tumor phenotype is about 10% to 15% by early adulthood. The increase in lymphoid malignancy includes both B- and T-cell tumors. However, young A-T patients do not show an increased susceptibility to cALL, and the UK data suggest that B-cell lymphoma occurs in older A-T children. T-cell tumors may occur at any age and may be T-ALL, T-cell lymphoma, or T-PLL; most strikingly, there may be a fourfold to fivefold increased frequency of T-cell tumors compared with that of B-cell tumors in these patients. If this is correct, it is possible that a significant proportion of all T-ALL/T-cell lymphoma in infants might be associated with undiagnosed A-T. The age range and sex predominance for T-ALL may be different for A-T and non-A-T patients and the age range for T-PLL may also be different in A-T and non-A-T patients. There is clearly some uncertainty concerning the ratio of T-cell to B-cell tumors in A-T, but this could be clarified by the publication of all tumors that occur in the disorder. In contrast, 8 of 9 tumors reported in NBS, which shows the same cellular features as A-T, were lymphomas and none was a leukemia. There are several indicators of genetic heterogeneity in A-T that suggest that not all patients are equally susceptible to all T-cell tumor types. Concordance for tumor type within individual families suggests that particular gene defects may be associated with particular tumor types. The logical extrapolation of this argument is that some patients may not have any increased risk for B-cell tumors at all or even to all T-cell types but only to a particular type of T-cell tumor. What is the cause of the increased predisposition to leukemia/lymphoma in A-T patients? There is no evidence that the immunodeficiency in A-T is related to this predisposition. One of the major findings in all A-T patients is the increase in V(D)J-mediated chromosome rearrangement observed in T lymphocytes. Particular chromosome translocations in T cells, involving a break in a TCR gene, are characteristically associated with either T-ALL or T-PLL in non-A-T patients. The majority of T-cell tumors in A-T are T-ALL and T-cell lymphoma, about which virtually nothing is known chromosomally, and the assumption is that the increased number of translocations leads to the increased level of these tumors. In older T patients, the expansion of specific translocation T-cell clones has been followed to the point to which they develop into T-PLL. All the evidence, therefore, suggests that the A-T mutation in the homozygous state allows a large increase in production of translocations formed at the time of V(D)J recombination, and this leads to the increased predisposition to leukemia. The general increased predisposition to T-cell tumors compared with B-cell tumors in A-T patients may be related to a preferential occurrence of translocations in T cells. Relatively little is known about translocations in circulating B lymphocytes in normal individuals, but A-T siblings have been shown to have clonal chromosome rearrangements of both B and T cells, simultaneously, although in these siblings the T-cell clones occupied all the T-cell compartment and the B-cell clones were small. An important inference from these facts is that the A-T defect preferentially affects immune system gene recombination in T cells rather than B cells. Recent evidence suggests that the V(D)J recombination machinery is not identical or is not regulated identically in T- and B-cell progenitors. This finding is consistent with the hypothesis that V(D)J rejoining in the majority, at least, of A-T patients may be preferentially deficient in T cells compared with B cells giving rise to the greatly increased number of translocations and T-cell tumors. Carbonari et al proposed that the recombination defect in A-T cells affected both Ig isotype switching and TCR rearrangeme
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PMID:Leukemia and lymphoma in ataxia telangiectasia. 855 63

Nijmegen breakage syndrome (NBS) is characterized by growth retardation, microcephaly, mental retardation, immunodeficiency, and predisposition to malignancies, especially B-cell lymphomas. In contrast, leukemia is rare. A 23-year-old NBS patient presented with anemia, thrombocytopenia, and hyperlymphocytosis. The diagnosis of T-cell prolymphocytic leukemia (T-PLL) was confirmed by cytological and immunological assays (TdT(-), CD2(+), CD5(+), CD3m, and CD7(+)). Biological assays also showed a hemolytic anemia and a clotting factor V decrease. The patient was first treated by methylprednisone for 3 weeks. During this period the lymphocyte count decreased. The simultaneous normalization of the hemolysis and of factor V suggested that both could be related to T-PLL. Since T-PLL is refractory to conventional therapies with a poor prognosis, an intensive chemotherapy such as 2'-deoxycoformycin with anti-CDw52 monoclonal antibodies is usually favored. In the present case, however, because of the specific context (i.e., NBS-induced immunodepression, severe hemolytic anemia, and acquired factor V deficiency), he received pentostatin weekly during 1 month and in maintenance during 6 months. At last follow-up (7 months) he showed a persistent control of the lymphocytosis with no side effect.
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PMID:T-cell prolymphocytic leukemia with autoimmune manifestations in Nijmegen breakage syndrome. 1284 81

The clinical phenotype of Ligase IV syndrome (LIG4 syndrome), an extremely rare autosomal recessive condition caused by mutations in the LIG4 gene, closely resembles that of Nijmegen breakage syndrome (NBS), and is characterized by microcephaly, characteristic facial features, growth retardation, developmental delay, and immunodeficiency. We report a 4(1/2)-year-old boy who presented with acute T-cell leukemia. The facial gestalt was strongly reminiscent of NBS. The patient died shortly after the onset of treatment for his T-cell leukemia. Subsequent chromosome breakage studies showed a high rate of breakage in a fibroblast culture. Radiosensitivity was assessed by a colony survival assay; the results showed radiosensitivity greater than is typically seen in NBS. Mutation screening of the NBS1 gene was negative. Sequencing of the LIG4 gene revealed a homozygous truncating mutation 2440 C>T (R814X). Although this mutation has been previously noted in LIG4 syndrome, this patient is the first reported homozygote for the mutation. In this study, we review the clinical features of this rare syndrome and provide suggestions for differential diagnosis.
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PMID:A patient with mutations in DNA Ligase IV: clinical features and overlap with Nijmegen breakage syndrome. 1608 10

Nijmegen breakage syndrome (NBS) is a human autosomal recessive disease characterized by genomic instability and enhanced cancer predisposition, in particular to lymphoma and leukemia. Recently, significantly higher frequencies of heterozygous carriers of the Slavic founder NBS1 mutation, 657del5, were found in Russian children with sporadic lymphoid malignancies, and in Polish adults with non-Hodgkin lymphoma (NHL). In addition, the substitution 643C>T (R215W) has also been found in excess among children with acute lymphoblastic leukemia (ALL). In an attempt to asses the contribution of both mutations to the development of sporadic lymphoid malignancies, we analyzed DNA samples from a large group of Polish pediatric patients. The NBS1 mutation 657del5 on one allele was found in 3 of 270 patients with ALL and 2 of 212 children and adolescents with NHL; no carrier was found among 63 patients with Hodgkin lymphoma (HL). No carriers of the variant R215W were detected in any studied group. The relative frequency of the 657del5 mutation was calculated from a total of 6,984 controls matched by place of patient residence, of whom 42 were found to be carriers (frequency = 0.006). In the analyzed population with malignancies, an increased odds ratio for the occurrence of mutation 657del5 was found in comparison with the control Polish population (OR range 1.48-1.85, 95% confidence interval 1.18-2.65). This finding indicates that the frequency of the mutation carriers was indeed increased in patients with ALL and NHL (p < 0.05). Nonetheless, NBS1 gene heterozygosity is not a major risk factor for lymphoid malignancies in childhood and adolescence.
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PMID:Carrier frequency of mutation 657del5 in the NBS1 gene in a population of Polish pediatric patients with sporadic lymphoid malignancies. 1615 6

Fanconi anaemia (FA) and Nijmegen breakage syndrome (NBS) carry a high risk of haematological cancer. Affected cellular pathways may be modulated in sporadic malignancies and silencing of FANCF through methylation has been shown to cause somatic disruption of the FA pathway. Combined bisulphite restriction analysis for methylation of FANCF, FANCB and NBS1 was used to investigate 81 sporadic acute childhood leukaemias. No methylation was detected at any associated CpG sites analysed. This does not exclude very low levels of FANCF, FANCB or NBS1 methylation, but suggests other factors are responsible for chemo-sensitivity and chromosomal instability in sporadic childhood leukaemia.
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PMID:No evidence of significant silencing of Fanconi genes FANCF and FANCB or Nijmegen breakage syndrome gene NBS1 by DNA hyper-methylation in sporadic childhood leukaemia. 1680 69

Therapy-related myelodysplasia and acute myeloid leukemia (t-MDS/AML) is a malignancy occurring after exposure to chemotherapy and/or radiotherapy. Polymorphisms involved in chemotherapy/radiotherapy response genes could be related to an increased risk of developing this neoplasia. We have studied 11 polymorphisms in genes of drug detoxification pathways (NQO1, glutathione S-transferase pi) and DNA repair xeroderma pigmentosum, complementation group (3) (XPC(3), X-ray repair cross complementing protein (1)), Nijmegen breakage syndrome (1), excision repair cross-complementing rodent repair deficiency, complementation group (5) and X-ray repair cross complementing protein (3) and in the methylene tetrahydrofolate reductase gene (MTHFR(2), 677C>T, 1298A>C), involved in DNA synthesis. The analyzed groups were a t-MDS/AML patients group (n=81) and a matched control group (n=64) treated similarly, and they did not develop t-MDS/AML. We found no significant differences when the groups were compared globally. However, when analysis was carried out according to the primary neoplasia involved, a significant association was observed between the MTHFR haplotype (single nucleotide polymorphisms 677 and 1298) and the risk of developing t-MDS/AML in the breast cancer patients group (P=0.016) and cyclophosphamide-treated hematological disease group (P=0.005). Risk haplotype was different for each case, corresponding to the 677T1298A haplotype after breast cancer treatment and the 677C1298C haplotype after hematological malignancy treatment. We postulate that such differences are related to variations in chemotherapy schemes between hematological and breast cancers and their differential interaction with the MTHFR route.
Leukemia 2007 Jul
PMID:Role of MTHFR (677, 1298) haplotype in the risk of developing secondary leukemia after treatment of breast cancer and hematological malignancies. 1747 81

Nijmegen breakage syndrome (NBS) is a rare auto-somal recessive condition with chromosomal instability. Clinical and biological overlap between Fanconi anemia and ataxia telangiectasia has been reported. We report two cases of NBS born to consanguineous parents. Case one had NBS and Falconi anemia clinical features but relatively little chromosome breakage. The second case had mild NBS features, while cytogenetic evaluation with mitomycin C induction showed chromosome damage. Chromosomal analysis of bone marrow cells revealed tetraploidy, which indicates progression towards leukemia. On the basis of clinical and cytogenetic evaluation, these two cases were confirmed as NBS. However, detailed molecular studies are essential for accurate diagnosis and management of this disease.
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PMID:Differentiation of Nijmegen breakage syndrome from Fanconi anemia. 1805 81

The MRN protein complex, consisting of MRE1, RAD50 and NBS1, plays a crucial role in sensing DNA double-strand breaks (DSBs), and it is involved in cell cycle control. This makes the MRN complex an important guard of genome stability. Hypomorphic mutations in NBS1 result in the Nijmegen breakage syndrome (NBS), which is characterized by, among other things, an increased predisposition to malignancies, especially leukemia/lymphoma. Relatives of NBS patients carrying heterozygous mutations are also more prone to cancer development. This review summarizes several studies searching for associations between heterozygous mutations in NBS1, MRE11, and RAD50 and cancer and examining the levels of expression of proteins coded by these genes in tumor tissues. The results indicate that both decreased and increased expression of NBS1 may contribute to tumorigenesis, whereas overexpressed RAD50 has an anti-tumoric effect. MRE11 and RAD50 are also affected in tumors with microsatellite instability. However, the outcomes of association studies, which concerned primarily lymphomas/leukemias and breast cancer, were inconclusive. Heterozygous NBS1 mutations and molecular variants 657del5, I171V, R215W and E185Q were most commonly analyzed. Among these, an association with cancer was found most frequently for 657del5 (in leukemia/lymphoma and breast cancer) and I171V (in leukemia, breast, head and neck and colorectal cancers); however, other studies gave contradictory results. For other NBS1 as well as MRE11 and RAD50 variants, too little data were available to assess their role in cancer risk. Overall, the results suggest that heterozygous MRN complex mutations and molecular variants may contribute only to a limited fraction of tumors. This may be caused by several factors: various frequencies of the variants in specific populations, different criteria used for selection of control groups, possible effects of environmental factors, and potential interactions with variants of other low-risk genes. These issues, as well as the impact of the alterations on protein function, need to be addressed in future studies.
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PMID:The importance of making ends meet: mutations in genes and altered expression of proteins of the MRN complex and cancer. 1860 67

Biallelic mutations in the NBS1 gene are responsible for the Nijmegen breakage syndrome (NBS), a rare autosomal recessive disorder characterized by chromosome instability and hypersensitivity to ionising radiation (IR). Epidemiological data evidence that the NBS1 gene can be considered a susceptibility factor for cancer development, as demonstrated by the fact that almost 40% of NBS patients have developed a malignancy before the age of 21. Interestingly, also NBS1 heterozygotes, which are clinically asymptomatic, display an elevated risk to develop some types of malignant tumours, especially breast, prostate and colorectal cancers, lymphoblastic leukaemia, and non-Hodgkin's lymphoma (NHL). So far, nine mutations in the NBS1 gene have been found, at the heterozygous state, in cancer patients. Among them, the 657del5, the I171V and the R215W mutations are the most frequently described. The pathogenicity of these mutations is presumably connected with their occurrence in the highly conserved BRCT tandem domains of the NBS1 protein, which are present in a large superfamily of proteins, and are recognized as major mediators of processes related to cell-cycle checkpoint and DNA repair.This review will focus on the current state-of-knowledge regarding the correlation between carriers of NBS1 gene mutations and the proneness to the development of malignant tumours.
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PMID:NBS1 Heterozygosity and Cancer Risk. 1945 44

Central nervous system (CNS) involvement is an independent risk factor for poor event-free survival and relapse confined to the CNS. Knock-out mice deprived of RAG2, the protein involved in DNA repair, developed leukemic infiltration within leptomeninges. Therefore, we hypothesized that DNA repair deficiencies in humans, such as Nijmegen breakage syndrome (NBS), may constitute a risk factor for CNS dissemination of acute lymphoblastic leukemia (ALL). Having analyzed the incidence of CNS2/CNS3 status at diagnosis of ALL in two independent cohorts from the Polish Pediatric Leukemia/Lymphoma Study Group, we noticed that among children with NBS CNS involvement was significantly frequent.
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PMID:Nijmegen breakage syndrome (NBS) as a risk factor for CNS involvement in childhood acute lymphoblastic leukemia. 2155 61

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