Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P04637 (p53)
 77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

There are few cytogenetic studies of early (non-invasive) bladder cancer, particularly in situ carcinoma, due to technical difficulties in examining such lesions. The best approach is to extrapolate from chromosomal changes in more advanced cancers. Although no specific chromosomal changes have been established in either early or fully developed bladder cancers, certain recurrent anomalies have been encountered. Anomalies such as +1, +7, -9, 5q- or i(5p), 11p- and -Y appear to constitute part of the multistep carcinogenetic process by which clinically and pathologically recognizable bladder cancers develop. Since loss of part or all of chromosome 9 (-9) is a common and early cytogenetic event in bladder cancer, the detection of -9 in bladder washings or urine by fluorescence in situ hybridization (FISH) may be a promising test for early or recurrent bladder cancer. Although less frequent than -9, trisomy 7 (+7) is common enough to serve a similar purpose. In contrast, loss of the Y chromosome may indicate an advanced stage of bladder cancer. Thus, FISH studies utilizing probes for chromosomes 7, 9, and Y should yield cogent information to identify early bladder cancer. Cytogenetic (including FISH) studies combined with certain molecular approaches (e.g., p53 mutations detected immunochemically) may not only serve to differentiate early cancer from benign tumors or conditions, but may also help establish cancer stage. This would supply data of considerable usefulness to the clinician and pathologist.
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PMID:Chromosome changes in early bladder neoplasms. 130 93

A 36-year-old woman was referred to our hospital because of splenomegaly in February 1989. The leukocyte count was 55,500/microliter without hiatus leukemicus. The leukocyte alkaline phosphatase score was low (29). The bone marrow showed myeloid hyperplasia (24.8% myeloblasts) but no dysplastic change. The karyotype of the bone marrow cells was 46, XX and a diagnosis of Ph1 (-) CML was made. Treatment with VCR, 6MP and prednisolone made 7-month duration chronic phase, but the abnormal karyotype.[46, XX, i(17q)] gradually increased to 100% of bone marrow cells. The patient died in June 1990. The evidence that not only a BCR rearrangement but also messages of BCR/ABL fusion gene were negative made us able to differentiate this case from Ph1(-), BCR(+) CML. The addition of an i(17q) results in partial monosomy of 17q (17q13;p53 gene) and partial trisomy of 17q (17q11.2-12;G-CSF gene). We examined the rearrangement of p53 gene and G-CSF-dependent tumor cell growth in vitro, demonstrating one allelic loss of p53 gene and independent cell growth on G-CSF respectively. It is thought that in Ph1 (-), BCR (-) CML as well as in Ph1 (+) CML, an i(17q) is related to the progression but not to the initiation of these leukemias. However the precise mechanism, including p53 gene inactivation by point mutation, is still to be elucidated.
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PMID:[i(17q) appearing in acute phase in Ph1-negative, BCR-negative CML]. 163 23

We describe a novel continuous B-cell line (PV-90) derived from a patient with myelodysplastic syndrome (MDS) and originating from spontaneous infection with the Epstein-Barr virus (EBV). The patient progressed to acute myeloblastic leukaemia (AML) 5 months after clinical onset of MDS. PV-90 is of clonal origin as indicated by the presence of immunoglobulin (Ig) gene rearrangements, monoclonal surface immunoglobulins, and a single DNA restriction fragment corresponding to the EBV genomic termini. PV-90 cells also express a number of myelomonocytic markers, including alpha-naphthyl acetate esterase (ANAE), coagulation factor XIII, and CD68 antigen. Moreover, PV-90 cells constitutively express the c-fms proto-oncogene mRNA as the patient's blast cells did. Whereas a trisomy 11 (+11) was found in the patient's bone marrow cells, PV-90 cells had a normal karyotype initially, but at 4 months showed two different and independent chromosomal abnormalities: 90, XX, -Y, -Y, t(9;16) (q11;p13), and 90, XX, -Y, -Y, t(17;18) (p13;q21), the latter possibly involving the p53 (17,p13) and bcl-2 (18, q21) proto-oncogenes. The early development of these chromosomal aberrations is consistent with a genetic instability of PV-90 cells. Expression of bi-lineage markers and genetic instability may suggest that PV-90 cells originated from transformation of a myelodysplastic progenitor cell capable of both myeloid and B-cell differentiation. The PV-90 cell line might be useful in a number of studies, including the possible role of c-fms in cell differentiation, pathogenetic mechanisms of human preleukaemia and lineage promiscuity in acute leukaemia.
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PMID:Establishment and characterization of a B-cell line derived from a patient with a myelodysplastic syndrome which expresses myelomonocytic and lymphoid markers. 164 72

Studies of multistage carcinogenesis in mouse skin have provided many of the early concepts of tumour initiation, promotion and progression. Genetic approaches have led to the identification of a number of mutational alterations in proto-oncogenes and tumour suppressor genes which take place at specific stages of carcinogenesis in this particular system. Initiation involves, at least in a proportion of tumours, mutational activation of the cellular H-ras proto-oncogene. Trisomy of chromosome 7, which develops during the premalignant clonal expansion phase, possibly as a consequence of tumour promoter treatment, is followed by further alterations on chromosome 7 which lead to a relative increase in the expression of mutant ras alleles. The p53 tumour suppressor gene undergoes mutational alteration and loss of heterozygosity in a proportion of squamous carcinomas but this particular gene does not appear to be involved in the further transition of squamous carcinomas to highly undifferentiated spindle cell tumours. The latter transition appears to be a recessive event which can be complemented by fusion with cells at earlier stages of malignancy. Mouse skin carcinogenesis therefore continues to provide invaluable information on the nature of the genetic and biological transitions which occur during the step-wise progression of normal cells to malignancy.
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PMID:Functional loss of tumour suppressor genes in multistage chemical carcinogenesis. 184 54

Cytogenetic analysis was performed on 16 primary tumors, 2 effusions, and 3 cell lines from 21 patients with non-small cell lung cancer (NSCLC). In 20 patients specimens were obtained prior to initiating cytotoxic therapy. Extensive clonal chromosome alterations were found in all cases. The most frequent numerical changes were polysomy 7 and polysomy 20 (each seen in 12 specimens). In addition, tumor cells from another six cases exhibited partial trisomy 7, with the shortest region of overlap (SRO) at 7p11-p13. Rearrangements of chromosomes 1, 3, 6, 8, 11, 15, 17, and 19 were each observed in nine or more tumors. Breakpoints were clustered at several chromosomal sites, including 1p13, 3p13, 15p11-q11, 17p11, and 19q13. Recurrent loss involving 1p, 3p, 6q, 11p, 15p, 17p, and 19q were each seen in at least eight cases. The SRO of 3p losses was at band 3p21. Double minute chromosomes were found in three tumors. Overall, our findings indicate that even though karyotypes in newly diagnosed NSCLC are very complex, recurrent cytogenetic changes can be identified. The high incidence of loss of 17p (14 of 21 specimens) appears to be compatible with reports implicating the TP53 gene (at band 17p13) as a frequent site for genetic alteration in lung cancer. Moreover, the recurrence of loss of 3p (12 cases) and 11p (10 cases) is also consistent with recent molecular evidence. The existence of other "hot spots" for cytogenetic change, particularly those involving specific regions on chromosomes 7, 15, and 19, warrants further molecular investigation of these sites in NSCLC.
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PMID:Chromosome alterations in 21 non-small cell lung carcinomas. 217 44

The chromosomal assignments of the two genes encoding the murine p53 cellular tumor antigen were determined by using a panel of mouse-Chinese hamster somatic cell hybrid clones and a mouse p53-specific cDNA clone. One gene, probably the functional member of the family, was found to be on chromosome 11. The other gene, which is probably a processed pseudogene, was assigned to chromosome 14. The potential relevance of these findings to documented cases of chromosome 11 trisomy are also discussed.
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PMID:The gene and the pseudogene for mouse p53 cellular tumor antigen are located on different chromosomes. 638 44

The development of cancer is a multistep process involving accumulation of genetic changes which progressively transform normal cells to neoplastic cells. During the last few years, our understanding and knowledge of the genetic changes involved in ovarian carcinogenesis have increased dramatically. In this review I will focus on karyotypic abnormalities in ovarian cancer and will also refer to molecular studies involving alterations in oncogenes and tumour suppressor genes in ovarian tumorigenesis. Cytogenetic analyses have identified two distinct subgroups. Simple karyotypic changes, trisomy 12 being the most common aberration in this group, are recurrently found in well differentiated ovarian carcinomas. Complex karyotypic abnormalities, including predominantly chromosome losses, deletions and unbalanced translocations, are found in moderately and poorly differentiated carcinomas. The bands and regions most commonly involved in structural rearrangements have been, in decreasing order of frequency, 19p13, 1p36, 1q21, 1q23-25, 3p11-13, 6q21, 19q13, 11p13-15, 11q13, 11q23, 12q24, 12p11-13, and 7p13-22. The finding of identical karyotypic and other genetic changes in tumour samples taken from different sites, such as tumours from both ovaries and omental metastases, indicate that ovarian cancer is of unicentric origin with subsequent metastatic spread giving rise to multiple implants. Molecular genetic changes important in ovarian cancer involve both classes of tumor-associated genes: RAS activation is generally not observed in ovarian cancer. Alterations of MYC1, ERBB2, AKT2, TP53 has been described in some ovarian carcinomas. The temporal relationship of these mutations, i.e. early or late events in ovarian carcinogenesis, remains to be determined.
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PMID:Genetic changes in ovarian cancer. 774 4

Allelotype analysis of human tumors has been instrumental in the effort to discover and clone novel tumor suppressor genes. However, this approach has not been systematically applied to animal models of carcinogenesis. We describe here the first attempt to allelotype a nonhuman tumor, i.e., chemically induced mouse skin tumors, using a panel of polymorphic microsatellite markers. The results indicated that markers on chromosomes 6 and 7 were imbalanced, consistent with trisomy in both benign and malignant skin tumors. A proportion of carcinomas also showed loss of heterozygosity on chromosome 11, where the p53 gene is located, and more rarely, on chromosomes 4, 6, and 15. The significance of these alterations is highlighted by the observations of no allelic imbalance for markers on 12 other chromosomes.
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PMID:Allelotype analysis of mouse skin tumors using polymorphic microsatellites: sequential genetic alterations on chromosomes 6, 7, and 11. 790 1

Although pediatric solid tumors are cytogenetically less well characterized than childhood leukemias, an understanding of the role of chromosomal changes in the development of these neoplasms is emerging. The major clinical importance of chromosome analysis today is diagnostic. Especially in small cell round cell tumors of childhood, the unique karyotypic patterns that characterize some of the differential diagnostic entities make it possible to determine with a high degree of certainty which type of cancer the child has. Molecular studies have revealed that almost all retinoblastomas show homozygous loss of function of the RB1 gene in 13q14. At the cytogenetic level, however, aberrations of 13q are seen in less than 25% of retinoblastomas; instead, the presumably progression-related i(6p) and aberrations leading to gain of 1q predominate, each being present in one-third of the tumors. Twenty percent of cytogenetically aberrant Wilms' tumors show structural rearrangements, often deletions, of 11p13 and 11p15, where the WT1 and WT2 genes map. Other frequent changes are trisomy 12 and duplication of 1q. The most common (80%) cytogenetic abnormality in neuroblastoma is loss of distal 1p, a chromosome segment thought to harbor at least two tumor-suppressor genes of importance in tumorigenesis. Double minute chromosomes or homogeneously staining regions are present in one-third of all neuroblastomas and are associated with MYCN amplification. Loss of 1p material or MYCN amplification predicts a poor outcome. The most common (30%) chromosomal aberration in primitive neuroectodermal tumors of the central nervous system is i(17q). The formation of this isochromosome may help inactivate a tumor-suppressor gene located distal to the TP53 locus on 17p. No specific chromosome abnormality has been detected in gliomas, but monosomy 22 and rearrangements leading to loss of 1p and gain of 1q are recurrent. Few hepatoblastomas with chromosomal changes have been reported, but several potential primary aberrations have been described, including +2, +20, and duplication 8q. In Ewing's sarcoma, t(11;22)(q24;q12) is the primary aberration, with trisomy 8 and gain of 1q being frequent secondary changes. Fibrosarcomas in children often carry only numeric aberrations, especially trisomy for chromosomes 11, 20, 17, and 8. Most osteosarcomas are cytogenetically complex, and no specific abnormality has been detected; the single most common change is loss of chromosome 13, which is observed in half the tumors. In contrast, the low-malignancy parosteal osteosarcomas often display supernumerary ring chromosomes as the sole karyotypic deviation. The cytogenetic profiles of rhabdomyosarcomas differ among the various morphologic subtypes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Cytogenetic analysis in the examination of solid tumors in children. 794 9

Genetic abnormalities are found in 50% of cases of chronic lymphocytic leukaemia (CLL) by cytogenetic analysis and in a higher percentage of patients using molecular techniques. The commonest cytogenetic abnormalities are trisomy 12 and deletions or translocations of the long arm of chromosome 13 usually involving band q14. The genetic consequences of trisomy 12 are unknown but structural abnormalities of chromosome 13q14 frequently involve hetero or homozygous loss of a region distal to the retinoblastoma gene which may be the site of a tumour suppressor gene. Trisomy 12 or loss of one copy of the retinoblastoma gene have been detected by fluorescent in situ hybridisation (FISH) in interphase cells of patients with a normal karyotype. By combining FISH with immunophenotyping, it has been found that trisomy 12 occurs in only 30 to 40% of the malignant clone, suggesting that it is a secondary event in leukaemogenesis. Trisomy 12 is strongly associated with atypical lymphocyte morphology in patients with otherwise typical CLL. Complex karyotypic abnormalities, a high percentage of abnormal metaphases and trisomy 12 but not structural abnormalities of chromosome 13 are associated with a poor prognosis at all stages of the disease. Mutations or deletions of the P53 gene are found in 10 to 15% of patients with advanced CLL and correlate with resistance to treatment and poor survival.
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PMID:Cytogenetic and molecular abnormalities in chronic lymphocytic leukaemia. 795 Apr 79


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