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Query: EC:5.99.1.3 (
topoisomerase
)
9,911
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Cyclins, the regulatory subunits of their respective cyclin-dependent kinases, are the key components of the cell-cycle progression machinery. Some cyclins are expressed discontinuously during the cell cycle, their synthesis and degradation being strictly scheduled. The presence of these cyclins in the cell, therefore, provides landmarks of the cell cycle, in addition to DNA replication and mitosis. Cyclin A is expressed in late S and G2 phase and degraded during mitosis just prior to metaphase. Degradation of another "mitotic" cyclin, cyclin B1, occurs later, at the transition from metaphase to anaphase. Based on the difference in time of degradation of
cyclin A
versus cyclin B1 it was possible, in the present study, to discriminate between G2 and mitotic (postprophase) MOLT-4 leukemic cells, by multiparameter (cellular DNA content versus cyclin expression) flow cytometry. The cells arrested in metaphase by Vinblastine were
cyclin A
negative and had an elevated level of cyclin B1. The cells arrested in G2 by the
DNA topoisomerase II
inhibitor m-AMSA had a very high level of cyclin B1 expression and unchanged expression of
cyclin A
. During stathmokinesis induced by Vinblastine the percentage of mitotic cells estimated by analysis of cellular DNA content and
cyclin A
expression was identical to that estimated by the alternative method based on in situ DNA denaturation followed by staining with acridine orange. Thus, differences in expression of cyclins A and B1 make it possible to discriminate cells that have the same DNA content but reside in different phases of the cycle, such as DNA diploid cells in G2 versus tetraploid G1 cells or mitotic versus G2 cells.
...
PMID:Discrimination of G2 and mitotic cells by flow cytometry based on different expression of cyclins A and B1. 766 39
In a series of 60 ALL samples drawn during different stages of the disease we used a cDNA-PCR approach to analyse the relative mRNA levels of the MDR-associated genes encoding mdr1/P-glycoprotein, mrp, and the
topoisomerase
II isozymes alpha and beta. Expression analysis of the
cyclin A
gene was included to examine cellular proliferation activity. The expression of gapdh served as an internal standard. Calculating the mean values we found: (i) a distinctly lower mdr1 gene expression in primary ALL and first relapses compared to bone marrow from healthy donors, (ii) no change in mdr1 and mrp, but a decreased topoisomerase II alpha gene expression in first relapses of ALL compared to the primary leukaemia, and (iii) increased mdr1 and mrp levels combined to decreased topoisomerase II alpha levels in recurrent relapses of ALL showing significant correlations (mdr1/mrp: rs = +0.6833, P < 0.05; mdr1/topoII alpha: rs = -0.6727, P < 0.05). The expression of the topoisomerase II alpha gene was correlated to that of
cyclin A
, indicating a link of its expression to cellular proliferation. Our findings suggest that a multifactorial MDR including mrp appears particularly in recurrent relapses of ALL, which often do not respond to chemotherapy. Nonetheless, some individual samples showed gene expression levels very different from the mean values calculated for a particular state of the leukaemia, indicating the need of an individual expression analysis of MDR-associated genes.
...
PMID:Expression of mdr1, mrp, topoisomerase II alpha/beta, and cyclin A in primary or relapsed states of acute lymphoblastic leukaemias. 787 86
Gene expression was analyzed by cDNA-PCR at the mRNA level in bone marrow samples (>80% blasts) from ALL (28 primary, 22 first relapses, 10 recurrent relapses), from AML (14 primary, 23 relapses), In peripheral blood lymphocytes from CLL (five untreated, 10 treated), in one CML in blast crisis in the course of the disease (four samples), and in bone marrow samples from healthy donors (12 specimens). We found low mean MDR1 expression in primary ALL, first relapses of ALL, and primary AML. Significantly higher mean relative MDR1 expression levels were seen in recurrent relapses of ALL, and in the group of relapsed state AML. MDR1 expression measured intermediate in bone marrow samples from healthy donors. The CLL lymphocytes showed generally relatively high MDR1 expression levels. MRP gene expression measured very similar in primary ALL, first relapses of ALL, primary AML, and normal bone marrow. Significantly increased MRP mRNA levels were observed in the groups of recurrent ALL and relapsed state AML. CLL lymphocytes also showed high MRP expression levels. A combined increase of MDRI (about 20-fold) and MRP (about four-fold) was monitored in samples obtained from the CML in blast crisis after chemotherapy. While no significant differences of the mean
topoisomerase
IIbeta mRNA levels were found throughout, a significantly decreased
topoisomerase
IIalpha gene expression was measured in first and recurrent relapses of ALL. In CLL lymphocytes either the expression of the
topoisomerase
IIalpha gene was not detectable by cDNA-PCR, or it measured very low. Topoisomerase IIalpha gene expression was correlated to
cyclin A
gene expression in the samples of acute leukemias, Indicating the link of
topoisomerase
IIalpha expression to the proliferative activity of these leukemic blast cells. Our results point to a potentially multifactorial emergence of multidrug resistance in particular states and types of leukemias.
...
PMID:MDR1, MRP, topoisomerase IIalpha/beta, and cyclin A gene expression in acute and chronic leukemias. 865 99
Amsacrine (4'-(9-acridinylamino)methanesulphon-m-anisidide) is an antileukemic drug which inhibits
topoisomerase
II (topo II) enzymes. We studied effects of two concentrations of amsacrine on the GM10115A cell line. This is a Chinese hamster line containing a single human chromosome 4, which can be readily visualised using fluorescence in situ hybridisation (FISH). The low amsacrine concentration slowed cell growth but did not cause significant arrest in the G2 phase of the cell cycle, while a higher concentration caused more long-term effects on the growth of the cells and caused G2 arrest. Either concentration led to chromosomal fragments which were lost with increasing time after treatment, and chromosomal translocations which appeared stable for at least 8 days after treatment. At the low concentration, the loss or gain of a single chromosome was a common event. The higher concentration led to polyploid cells, usually containing an uneven number of chromosome 4. We propose two mechanisms for aneuploidy by amsacrine (or related topo II poisons), either of which can be readily detected using FISH. At low drug concentrations, aneuploidy may occur directly through, for example, a failure to resolve catenated chromatids prior to anaphase. However, there has been considerable interest in the role of the cell division control (cdc) kinase and cyclins in regulating the mammalian cell cycle, and these may also be involved in the response of cells to high concentrations of topo II poisons. Cdc2 proteins and cyclins are involved in coordinating diverse activities during the M phase of the cell cycle, including catalysis of chromosome condensation and reorganisation of microtubules to allow chromosome separation during mitosis. Chromosome damage by topo II poisons will lead to G2 arrest, which allows the cells time to repair the damage. During this time,
cyclin A
and cdc2 levels will fall, preventing the cell from entering mitosis and effectively resetting the clock to G1 and the ploidy to tetraploid. Aneuploid cells will derive from polyploid cells through loss of extra chromosomes.
...
PMID:Application of fluorescence in situ hybridisation to study the relationship between cytotoxicity, chromosome aberrations, and changes in chromosome number after treatment with the topoisomerase II inhibitor amsacrine. 866 70
A possible link between protein kinase C (PKC) and P-glycoprotein (P-gp)-mediated-multidrug resistance (MDR) was assumed from studies on MDR cell lines selected in vitro. The functional relevance of PKC for the MDR phenotype remains unclear, and the involvement of a particular PKC isozyme in clinically occurring drug resistance is not known. Recently, we have demonstrated significant correlations between the expression levels of the PKC eta isozyme and the MDR1 or MRP (multidrug resistance-associated protein) genes in blasts from patients with acute myelogenous leukaemia (AML) and in ascites cell aspirates from ovarian cancer patients. To extend these findings to further types of human tumours we analysed specimens from 64 patients with primary breast cancer for their individual expression levels of several MDR-associated genes (MDR1, MRP, LRP (lung cancer resistance-related protein),
topoisomerase
(Topo) II alpha/IIbeta,
cyclin A
and the PKC isozyme genes (alpha, beta1, beta2, eta, theta, and mu) by a cDNA-PCR approach. We found significantly enhanced mean values for MRP, LRP and PKC eta gene expression, but significantly decreased Topo II alpha and
cyclin A
gene expression levels in G2 tumours compared with G3. Remarkably, significant positive correlations between the MDR1, MRP or LRP gene expression levels and PKC eta were determined: MDR1/PKC eta (rs = +0.6451, P < 0.0001) n = 62; MRP/PKC eta (rs = +0.5454, P < 0.0001) n = 63; LRP/PKC eta (rs = +0.5436, P < 0.0001) n = 62; MRP/LRP (rs = +0.7703, P < 0.0001) and n = 62, MDR1/MRP (rs = +0.5042, P < 0.0001) n = 62. Our findings point to the occurrence of a multifactorial MDR in the clinics and to PKC eta as a possible key regulatory factor for up-regulation of a series of MDR-associated genes in different types of tumours.
...
PMID:Multiple gene expression analysis reveals distinct differences between G2 and G3 stage breast cancers, and correlations of PKC eta with MDR1, MRP and LRP gene expression. 945 50
Genistein is an isoflavone known to inhibit both tyrosine protein kinase and
DNA topoisomerase II
. We have investigated the mechanism of genistein-induced growth inhibition in MCF-7 and MDA-MB-231 breast carcinoma cell lines. DNA flow cytometric analysis indicated that genistein induced a G2/M arrest in both cell lines. Therefore, we examined the effect of genistein on cell cycle-related proteins. Western blot analysis using whole cell lysates from MCF-7 and MDA-MB-231 treated with genistein demonstrated that genistein treatment did not change the steady-state level of cdks,
cyclin A
, D-type cyclins and cyclin E protein, but inhibited expression of cyclin B1 protein in a time-dependent manner. The reduction in the protein level of cyclin B1 correlated with a decrease in the level of cyclin B1 mRNA. Genistein induced expression of p21, and the increased levels of p21 were associated with increased binding of p21 with cdc2 and cdk2. These observations suggest that genistein induces a G2/M arrest in human breast cancer cells, the mechanism of which is in part due to inhibition of kinase activities of cdc2 and cdk2, and decrease in cyclin B1 expression.
...
PMID:Genistein-induced G2/M arrest is associated with the inhibition of cyclin B1 and the induction of p21 in human breast carcinoma cells. 966 38
Induced cell cycle delays were among the first described cellular responses to ionizing radiation (IR). To understand the sensitivity and the molecular events involved in the response to low doses of IR and to examine the role of p53 and its downstream effector p21Waf1, we measured changes in expression of genes postulated to be involved in the cellular response to IR. Expression levels were examined in normal human diploid fibroblasts irradiated and maintained in quiescent density-inhibited growth up to 24-48 h after exposure to X-ray doses as low as 0.1-0.3 Gy, which have negligible effects on cell survival. Among 31 genes analyzed, we observed down-regulation in response to IR of the mRNA levels of CDC2,
cyclin A
, cyclin B, thymidine kinase,
topoisomerase
IIalpha, and RAD51. A similar reduction in the expression levels of these genes occurred when irradiated cells were released from confluence and allowed to proliferate. This was not observed in cells in which p53 function was defective and up-regulation of p21Waf1 levels either did not occur (E6 transfected normal human fibroblasts and Li-Fraumeni fibroblasts) or was delayed (ataxia telangiectasia fibroblasts) after irradiation. Down-regulation was also absent in p21Waf1-null mouse embryo fibroblasts (MEFs) but occurred at a lower level in p53-null MEFs, due to slight increases in p21Waf1 levels by a p53-independent pathway. These findings indicate that the down-regulation of these cell cycle regulated genes in irradiated cells is p53-dependent and involves its effector p21Waf1. Although no down-regulation in the expression of genes involved in G2-M was observed in p53 or in p21Waf1-null MEFs, these cells showed a G2-M delay after irradiation, indicating that the expression levels of these genes does not regulate the G2-M delay.
...
PMID:Regulation by ionizing radiation of CDC2, cyclin A, cyclin B, thymidine kinase, topoisomerase IIalpha, and RAD51 expression in normal human diploid fibroblasts is dependent on p53/p21Waf1. 983 Dec 41
Our previous work has demonstrated that treatment of NIH 3T3 cells with etoposide (VP16), an inhibitor of
DNA topoisomerase II
and widely used anticancer agent, results in G2/M-phase arrest, whereas treatment of cells transformed by v-src, v-ras, or v-raf results in an S-phase blockage. The present studies describe the mechanistic aspects of this selective S-phase arrest in the v-src-transformed cells. The S-phase arrest in these cells was found to be coupled with depletion of
cyclin A
-dependent kinase activity. This decrease could not be explained by changes in the overall level of
cyclin A
, CDK2, p27, or p21 proteins. Rather, it was associated with a time-dependent reduction of CDK2 protein complexed with
cyclin A
following VP16 treatment. It was further shown that the decrease of
cyclin A
-associated CDK2 was linked to an increase of CDK2 protein in cyclin E immunocomplexes, which suggests that CDK2 might become redistributed following treatment with VP16. Thus, oncogenic transformation by v-src can trigger separation of CDK2 protein from
cyclin A
in response to VP16. This might contribute to the depletion of
cyclin A
-dependent kinase activity and the selective S-phase arrest by VP16 in v-src-transformed cells.
...
PMID:Dissociation of CDK2 from cyclin A in response to the topoisomerase II inhibitor etoposide in v-src-transformed but not normal NIH 3T3 cells. 1036 32
Entry into mitosis is controlled by the cyclin-dependent kinase CDK1 and can be delayed in response to DNA damage. In some systems, such G(2)/M arrest has been shown to reflect the stabilization of inhibitory phosphorylation sites on CDK1. In human cells, full G(2) arrest appears to involve additional mechanisms. We describe here the prolonged (>6 day) downregulation of CDK1 protein and mRNA levels following DNA damage in human cells. This silencing of gene expression is observed in primary human fibroblasts and in two cell lines with functional p53 but not in HeLa cells, where p53 is inactive. Silencing is accompanied by the accumulation of cells in G(2), when CDK1 expression is normally maximal. The response is impaired by mutations in cis-acting elements (CDE and CHR) in the CDK1 promoter, indicating that silencing occurs at the transcriptional level. These elements have previously been implicated in the repression of transcription during G(1) that is normally lifted as cells progress into S and G(2). Interestingly, we find that other genes, including those for CDC25C,
cyclin A2
, cyclin B1, CENP-A, and
topoisomerase
IIalpha, that are normally expressed preferentially in G(2) and whose promoter regions include putative CDE and CHR elements are also downregulated in response to DNA damage. These data, together with those of other groups, support the existence of a p53-dependent, DNA damage-activated pathway leading to CHR- and CDE-mediated transcriptional repression of various G(2)-specific genes. This pathway may be required for sustained periods of G(2) arrest following DNA damage.
...
PMID:Repression of CDK1 and other genes with CDE and CHR promoter elements during DNA damage-induced G(2)/M arrest in human cells. 1071 60
A tumor-suppressor gene, p16(INK4), which is deleted or mutated in tumors, regulates cell-cycle progression through a G(1)-S restriction point by inhibiting CDK4(CDK6)/cyclin-D-mediated phosphorylation of pRb. We have found that ectopic p16(INK4) expression increased cellular sensitivity of human non-small-cell-lung-cancer (NSCLC) A549 cells to a selective growth-inhibitory effect induced by the
topoisomerase
-I inhibitor 11, 7-ethyl-10-[4-(1-piperidino)-1-piperidino] carbonyloxy camptothecin (CPT-11) in vitro. In this study, we observed enhanced apoptosis characterized by DNA fragmentation in A549 cells transfected with p16(INK4) cDNA (A549/p16-1) and treated with CPT-11. This apoptosis was suppressed by the inhibitor of interleukin-1beta-converting enzyme (ICE/caspase-1) or ICE-like proteases, Z-Asp-CH2-DCB, as determined by DNA fragmentation and proteolytic cleavage of poly(ADP-ribose) polymerase, a natural substrate for CPP32/caspase-3. In A549/p16-1 cells, cytosolic peptidase activities that cleaved Z-DEVD-7-amino-4-trifluoromethylcoumarin increased during CPT-11-induced apoptosis and were suppressed by a highly specific caspase-3 and caspase-3-like inhibitor, Z-DEVD-fluoromethylketone. These findings indicate that p16(INK) is positively involved in the activation pathway of the caspase-3 induced by CPT-11. The increased delay in S-phase progression and subsequent induction of apoptosis were observed in CPT-11-treated A549/p16-1 cells on the basis of DNA histograms. Specific down-regulation of the cyclin-A protein level in A549/p16-1 cells was observed after CPT-11-treatment, whereas cyclin B, cdk2, and cdc2 protein levels were unaffected. These results suggest that ectopic p16(INK4) expression inappropriately decreases
cyclin A
and thereby terminates CPT-11-induced G(2)/M accumulation, which is followed by increased apoptosis in p16(INK4)-expressing A549 cells.
...
PMID:Ectopic p16(ink4) expression enhances CPT-11-induced apoptosis through increased delay in S-phase progression in human non-small-cell-lung-cancer cells. 1073 46
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