UNIPROT:P04637 - FACTA Search

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

P53 protein, Ki67 proliferative associated antigen and DNA content have been studied by flow cytometry in the blood blastic cells from 41 patients with acute leukemia. The results were compared with the F.A.B. classification. Cells were permeabilised and fixed by PLP solution before using the FITC conjugated Ki67 MoAb and the p53 MoAb (clone 1801). Propidium iodide and RNAase has been used in order to determine ploidy. Ki67 and p53 protein were found to be expressed at higher level in leukemia cells than in normal bone marrow cells; however there was no correlation between Ki67 and p53 expression and F.A.B. subtype. In acute leukemia patients the range of positivity of Ki67 was 1.1-52.1% while it ranged from 1.8% to 80.1% for the p53 protein. On the basis of these findings we conclude that the flow cytometry evaluation of Ki67 and p53 represents a useful tool for the study of the biologic characteristics of the leukemic cells in patients with acute leukemia.
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PMID:[Fluorocytometric study of proliferation antigens, nuclear proteins and ploidy in acute leukosis]. 129 14

The frequent occurrence of TF gene involvement in translocations associated with leukemia is remarkable, although not yet explained. The wide variety of TFs involved in these translocations and the different stages of cellular maturation argue against a unifying mechanism. Recombinases, active during B-cell and T-cell development, have been implicated in gene arrangements involving TCR genes and in the SIL/SCL rearrangement, which involves two genes not normally rearranged. However, other mechanisms must clearly be active in generating these molecular abnormalities and perhaps they relate to the multistep maturation and differentiation processes and continuous cell turnover seen in hematopoietic cells. The difficulties in obtaining human solid tumor samples may make it more difficult to identify translocations involving TF genes in solid tumors. Recently, the cytogenetic analysis of solid tumors has improved and specific cytogenetic abnormalities have been associated with specific types of tumors. With advanced techniques, such as fluorescent in situ hybridization (a technique that does not depend on cell growth) and PCR, abnormalities involving TF genes will be discovered. Abnormalities of TF genes, other than translocations, have been seen in a broad variety of nonhematopoietic malignancies. The p53 protein has been shown to bind DNA in a sequence-specific fashion and interact with a variety of DNA tumor virus oncoproteins. The broad range of cell types that harbor p53 abnormalities suggests that TF abnormalities will likely be implicated in many solid tumors. We have detailed several examples of how gene rearrangements that accompany chromosomal translocations in acute leukemia can alter the expression or activity of cellular TFs. Several translocations generate fusion RNA transcripts and fusion TF proteins with altered functional characteristics. Other translocations result in the expression of a gene not normally detectable in hematopoietic cells or alter the level of its expression, or affect the promoter usage or exon structure of the gene (Table 2). Studies are underway in many laboratories to characterize the biologic activity of these abnormal TFs and it remains to be proven that these molecular abnormalities are directly linked with leukemogenesis. The identification of abnormal fusion transcripts and proteins may allow specific therapies to be directed against "tumor-specific" DNA, mRNA, or protein targets. Therapeutic strategies based on antisense or ribozyme technology may be used to turn off expression of these genes and inhibit leukemia cell growth. Immunologic methods can also be used to direct therapy against the malignant cells.
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PMID:Transcription factors, translocations, and leukemia. 136 70

We analyzed the structural alteration of the p53 gene, by Southern blotting with conventional and/or pulsed-field gel electrophoresis, in patients with Philadelphia chromosome-positive leukemia (chronic myelogenous leukemia; CML, 34 cases and acute leukemia; AL, 5 cases). We found an alteration of the p53 gene in one of 5 AL patients. Loss of heterozygosity was detected in two CML patients with i(17q) chromosome, but we could find no other alterations in the remaining CML patients.
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PMID:Alterations of the p53 gene in Philadelphia chromosome-positive leukemia including chronic myelogenous leukemia and acute leukemia. 139 1

Chronic myelocytic or Ph1-positive acute lymphoblastic leukemias have been analyzed for alterations in a variety of proto-oncogenes and anti-oncogenes implicated in the progression of chronic myeloid leukemia (CML) from its chronic phase to blast crisis. The most frequent genetic change found in disease evolution is an alteration of the p53 gene involving a point mutation, a rearrangement or a deletion. These gene changes are common in myeloid and undifferentiated variants of blast crisis but are usually undetectable in lymphoid leukemic transformants. Other molecular changes also occur in the clonal evolution of CML. The retinoblastoma-susceptibility (Rb) gene is an anti-oncogene. Structural abnormalities of Rb are frequent in all types of human acute leukemia, but are particularly common in Ph1-positive leukemia of lymphoid phenotype including both Ph1-positive ALL and lymphoid blast crisis of CML. Changes in Rb occur early in the transition to blast crisis with loss of Rb protein being the common factor. Mutations in the N-RAS gene also occur, but are rare in typical blast crisis. They are sometimes seen in Ph1-negative myeloid blast crisis. Since changes in the p53 gene are generally associated with progression of disease of a myeloid phenotype and changes in the Rb gene occur more often with a lymphoid phenotype, a particular molecular alteration may influence the character of disease evolution in CML.
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PMID:Molecular mechanisms in the evolution of chronic myelocytic leukemia. 149 27

The p53 gene encodes a nuclear phosphoprotein and is now considered as a tumor suppressor gene. Mutations of the p53 gene have frequently been observed in several types of solid tumors and are believed to be implicated in the development of these tumors. Recent studies have shown that the p53 gene is altered in chronic myelogenous leukemia (CML) in blast crisis. In CML, alterations of the p53 gene may play an important role in the development of blast crisis. More recently, p53 mutations have been reported in other types of hematologic neoplasms, such as acute leukemia, adult T-cell leukemia, and malignant lymphoma. These observations suggest that inactivation of the p53 gene is involved in the tumorigenesis of various types of hematologic neoplasms.
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PMID:[Mutations of the p53 gene in hematologic neoplasms]. 151 57

Germline p53 mutations have been identified in the Li-Fraumeni syndrome but the role of such mutations in familial leukemia is not established. The p53 gene was examined by single-strand conformation polymorphism analysis of exons 4-8 in 10 families with multiple members affected with leukemia. The diagnoses included acute and chronic leukemias and Hodgkin's disease. Identified in two families were p53 mutations that were nonhereditary. These included a 2-bp deletion in exon 6 found in the lymphoblast DNA of one child whose sibling, cousin, and several adult relatives had acute leukemia. The other nonhereditary p53 mutation was a transition at codon 248 (CGG to CAG, arginine to glutamine) found in the lymphoblasts of a patient with a preleukemic syndrome and acute lymphoblastic leukemia (ALL) whose brother is a long-term survivor of ALL. Thus, p53 mutations were found to occur in two families but both were nonhereditary. Moreover, in the remaining eight families no p53 mutation was identified in the regions of p53 where most mutations have been found in other cancers. Although p53 mutations sometimes may be present, they do not appear to be a primary event responsible for hereditary susceptibility to familial leukemia. This study suggests involvement of other genes or mechanisms.
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PMID:Absence of hereditary p53 mutations in 10 familial leukemia pedigrees. 164 30

Independent mutations in both alleles of the p53 tumor suppressor gene are a frequent finding in human T-cell acute lymphoblastic leukemia (T-ALL) cell lines and in the cells of some T-ALL patients in relapse. One major goal of studying the status of p53 (and other tumor suppressor genes) in human cancer is to facilitate the suppression of the tumorigenic phenotype through the restoration of the expression of the wild-type allele. While the efficient insertion of a suppressor into all cells of solid/metastatic human tumors may at present be impossible, insertion into leukemia cells may be feasible due to the accessibility of the leukemia cells in the body. To examine the feasibility of suppressing the tumorigenicity of human T-leukemia cells, the human T-ALL cell line Be-13, which lacks endogenous p53 protein, was infected with a recombinant retrovirus encoding the wild-type allele of human p53 (hwtp53). Expression of p53 reduced the growth rate of infected Be-13 cells in vitro, suppressed colony formation in methylcellulose cultures, and abrogated their tumorigenic phenotype in nude mice in vivo. These results suggest that suppression of the leukemic phenotype of relapse T-ALL-derived Be-13 cells is feasible. Acute leukemia cell suppression via high-efficiency infection with retroviruses encoding wtp53 may be feasible and beneficial in T-ALL cases as part of a bone marrow transplantation regimen in an effort to reduce the frequency of posttransplantation relapse.
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PMID:Suppression of acute lymphoblastic leukemia by the human wild-type p53 gene. 172 82

Expression of p53 oncogene in blast cells may have prognostic importance in acute leukemia. Simple and reliable methods which could detect enhanced p53 expression in leukemia cells would be important for follow-up studies of leukemia patients in remission. We used immunoperoxidase (IP) technique with an anti-p53 monoclonal antibody PAb421 to study the expression of p53 in leukemia cells. The expression of p53 was studied in 9 cell lines and 17 de novo acute leukemia (9 acute myeloid leukemia [AML], 8 acute lymphoblastic leukemia [ALL]) patients. The expression of p53 was demonstrated in non-T non-B cells and Burkitt's lymphoma cell lines, but neither in two myeloid leukemia cell lines nor in normal lymphoid cells after mitogenic stimulation. p53 expression was demonstrated in 7 cases (2 AML, 5 ALL) but only in ALL cases the percentage of positive of cells was over 20%. Bone marrow cells from patients were studied also after short-term culture (AML patients); in 1 case the number of PAb421-positive cells rose significantly after culture. These data suggest that IP staining with PAb421 can be used to demonstrate high p53 expression in B cell leukemias.
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PMID:Detection of p53 oncogene in acute-leukemia cells by immunoperoxidase technique. 185 83

Chronic myelogenous leukemia (CML) is the best understood human cancer. The molecular basis of CML involves activation of a cellular proto-oncogene--ABL. The consequence is to increase tyrosine kinase activity. This results in a marked clonal increase in the myeloid mass. Later on, cellular maturation is blocked and the decrease eventuates in acute leukemia. Abnormalities of other proto-oncogenes or antioncogenes, like P53, may be involved in leukemia progression. Treatment of CML involves chemotherapy and, more recently, interferon. Whether this treatment prolongs survival or increases the likelihood of cure is unknown but either result seems unlikely. Bone marrow transplants which cure about 50% of persons with CML are most effective when performed in chronic phase.
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PMID:Chronic myelogenous leukemia: molecule to man. 189 3

Two new myeloid cell lines (K051 and K052) were established from a patient with multilineage CD7-positive acute leukemia. The K051 and K052 were established from the patient's bone marrow cells at diagnosis and at relapse, respectively. The K051 cell expressed myeloid-associated antigens (CD13 and CD33), a platelet-associated antigen (CD41), and an erythroid antigen (glycophorin A). The K052 cell expressed myeloid-associated antigens (CD13, CD14, and CD33), lymphoid markers (CD2, CD5, and CD7), and HLA-DR. Chromosome analysis of both cell lines showed a 17p- chromosome. Both cell lines were investigated for aberrations of the p53 gene and the N-ras gene. A p53 mutation detected in both cell lines consisted of a C-->T substitution in codon 248. An N-ras mutation detected only in the K052 cell consisted of a G-->C substitution in codon 13. Expression of the multidrug resistance gene (MDR1) was also investigated by the semiquantitative reverse transcriptase-polymerase chain reaction (RT-PCR). MDR1-mRNA was more highly expressed by the K052 cell than the K051 cell, being equivalent to that in HEL cells. The functional MDR1-protein against vincristine was also observed, and its function was inhibited by verapamile and Cyclosporin A. The K052 cells were capable of phenotypic or morphologic differentiation after being incubated with granulocyte colony-stimulating factor, interleukin-2, phorbol 12-myristate 13-acetate, or 1,25-dihydroxy-vitamin D3. In contrast, the K051 cells responded phenotypically to retinoic acid. Thus, the K051 and K052 cell lines will be useful for investigating the cellular and molecular events in leukemogenesis and differentiation, and the mechanism of expression of the MDR1 gene.
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PMID:p53 and N-ras mutations in two new leukemia cell lines established from a patient with multilineage CD7-positive acute leukemia. 769 50

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