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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)
Previous studies have demonstrated that G1/S cell cycle blockers and inhibitors of cyclin-dependent kinases (CDKs) prevent the death of nerve growth factor (NGF)-deprived PC12 cells and sympathetic neurons, suggesting that proteins normally involved in the cell cycle may also serve to regulate neuronal apoptosis. Past findings additionally demonstrate that DNA-damaging agents, such as the
DNA topoisomerase
(topo-I) inhibitor camptothecin, also induce neuronal apoptosis. In the present study, we show that camptothecin-induced apoptosis of PC12 cells, sympathetic neurons, and cerebral cortical neurons is suppressed by the G1/S blockers deferoxamine and mimosine, as well as by the
CDK
-inhibitors flavopiridol and olomoucine. In each case, the IC50 values were similar to those reported for inhibition of death induced by NGF-deprivation. In contrast, other agents that arrest DNA synthesis, such as aphidicolin and N-acetylcysteine, failed to block death. This suggests that the inhibition of DNA synthesis per se is insufficient to provide protection from camptothecin. We find additionally that the cysteine aspartase family protease inhibitor zVAD-fmk inhibits apoptosis evoked by NGF-deprivation but not camptothecin treatment. Thus, despite their shared sensitivity to G1/S blockers and
CDK
inhibitors, the apoptotic pathways triggered by these two causes of death diverge at the level of the cysteine aspartase. In summary, neuronal apoptosis induced by the DNA-damaging agent camptothecin appears to involve signaling pathways that normally control the cell cycle. The consequent death signals of such deregulation, however, are different from those that result from trophic factor deprivation.
...
PMID:G1/S cell cycle blockers and inhibitors of cyclin-dependent kinases suppress camptothecin-induced neuronal apoptosis. 900 70
Three DNA damage-responsive cell cycle checkpoints can be shown to operate in diploid human fibroblasts. One checkpoint arrests growth in G1, another inhibits replicon initiation in S phase cells, and the third delays progression from G2 into mitosis. Progression from G2 into M is controlled in part by a
cyclin-dependent kinase
(cyclin B/Cdk1) that is regulated by tyrosine phosphorylation. Phosphorylation of Tyr15 on Cdk1 is inhibitory for kinase activity. Activation of cyclin B/Cdk1 at the onset of mitosis is accomplished by a phosphatase, Cdc25C, that interacts with cyclin B/Cdk1 in an autocatalytic feedback loop to remove the inhibitory phosphate at Tyr15 and activate kinase activity. DNA damage triggers G2 delay by inhibiting formation of the autocatalytic feedback loop so that dephosphorylation of Tyr15 does not occur. This suppression of activation of cyclin B/Cdk1 appears to account for the failure of damaged G2 cells to progress into mitosis. Once the damage to DNA is repaired, cells resume progression into mitosis as the cycle is re-engaged. The isoflavone genistein inhibits tyrosine kinases, including one that phosphorylates Cdk1 on Tyr15. This kinase, p56/p53lyn is rapidly induced by treatments that trigger cell cycle checkpoints (ionizing radiation, cytosine arabinoside), suggesting that this kinase may actively delay the onset of mitosis by phosphorylating Tyr15 on Cdk1. Genistein also inhibits
type II DNA topoisomerase
to produce a form of DNA damage that triggers all of the DNA damage-responsive cell cycle checkpoints. A brief 10 min incubation with the
topoisomerase
poison amsacrine was sufficient to trigger the S phase checkpoint response and inhibit replicon initiation. Inhibition of replicon initiation by 1 microM amsacrine was maximal 20-30 min after drug treatment and by 120 min, the checkpoint response had decayed to allow near control rates of replicon initiation. Topoisomerase II poisons also are powerful clastogens inducing lethal and carcinogenic chromosomal aberrations. Type II
topoisomerase
can break DNA in a region of chromosome 11q23 that contains the ataxia telangiectasia gene (ATM). The ATM gene controls all of the DNA damage-responsive cell cycle checkpoints. Chromosomal aberrations in 11q23 are frequently seen in acute myeloid leukemia that develops as a consequence of etoposide chemotherapy. Thus,
topoisomerase
poisons such as genistein may trigger chromatid breakage to inactivate AT gene function, disable cell cycle control, and induce genetic instability.
...
PMID:Human topoisomerase II function, tyrosine phosphorylation and cell cycle checkpoints. 949 43
DNA topoisomerase II
(topo II) is an essential nuclear enzyme required for chromatin condensation and chromosome segregation during mitosis. Forced overexpression of topo IIalpha was found to cause morphological changes in recipient cells associated with apoptosis. This induction of apoptosis required nuclear localization of topo IIalpha, yet was independent of the DNA cleavage-religation activity of the enzyme. Apoptosis mediated by topo IIalpha deregulation was blocked by overexpression of crmA, a specific inhibitor of certain caspases, but not by bcl-2. topo IIalpha-induced apoptosis was also blocked by overexpression of a dominant-acting mutant of stress-activated protein kinase kinase (SEK1/MKK4) but not by the overexpression of its normal counterpart. Furthermore, apoptosis was blocked by coexpression of a dominant-negative form of the
cyclin-dependent kinase
cdk2 but not by dominant-negative cdc2. These results provide a rationale for the tight regulation of topo IIalpha levels through the cell cycle in that deregulation of topo IIalpha expression results in apoptotic cell death.
...
PMID:Induction of apoptosis by deregulated expression of DNA topoisomerase IIalpha. 978 93
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
In most cases, the histopathologic and cytologic distinction between Graves' disease and papillary thyroid carcinoma is relatively easy, but on occasion Graves' disease may simulate a thyroid papillary carcinoma. For example, papillary fronds with fibrovascular cores may be present in both Graves' disease and papillary carcinoma. p27kip1 (p27) is a
cyclin-dependent kinase
inhibitory protein that has been shown to be an independent prognostic factor in a variety of human tumors. Our previous studies of p27 expression in hyperplastic and neoplastic endocrine lesions showed that the level of p27 was quite different in these two conditions. To determine if this distinction could also be made between Graves' disease and papillary carcinoma, we analyzed expression of p27 and other cell cycle proteins in a series of cases of Graves' disease with papillary hyperplasia and a series of papillary thyroid carcinomas. Formalin-fixed paraffin-embedded tissues from 61 randomly selected patients with thyroid disease, including 29 cases of Graves' disease with papillary architectural features and 32 cases of papillary carcinoma, were analyzed for expression of p27, Ki-67, and
DNA topoisomerase II
alpha (topo II alpha) by immunostaining. The distribution of immunoreactivity was analyzed by quantifying the percentage of positive nuclei that was expressed as the labeling index (LI) plus or minus the standard error of the mean. The papillary hyperplasia of Graves' disease had a p27 LI of 68.2 +/- 3.1 (range, 24 to 88), whereas papillary carcinomas had a LI of 25.6 +/- 2.5 (range, 12 to 70) (P < .0001). No significant differences in Ki-67 or topo II alpha expression were identified between papillary hyperplasia in Graves' disease and papillary carcinoma. These results indicate that p27 protein expression is significantly higher in papillary hyperplasia of Graves' disease compared to papillary carcinoma, which may be diagnostically useful in difficult cases.
...
PMID:p27kip1 expression distinguishes papillary hyperplasia in Graves' disease from papillary thyroid carcinoma. 1100 42
p53 protects mammals from neoplasia by inducing apoptosis, DNA repair and cell cycle arrest in response to a variety of stresses. p53-dependent arrest of cells in the G1 phase of the cell cycle is an important component of the cellular response to stress. Here we review recent evidence that implicates p53 in controlling entry into mitosis when cells enter G2 with damaged DNA or when they are arrested in S phase due to depletion of the substrates required for DNA synthesis. Part of the mechanism by which p53 blocks cells at the G2 checkpoint involves inhibition of Cdc2, the
cyclin-dependent kinase
required to enter mitosis. Cdc2 is inhibited simultaneously by three transcriptional targets of p53, Gadd45, p21, and 14-3-3 sigma. Binding of Cdc2 to Cyclin B1 is required for its activity, and repression of the cyclin B1 gene by p53 also contributes to blocking entry into mitosis. p53 also represses the cdc2 gene, to help ensure that cells do not escape the initial block. Genotoxic stress also activates p53-independent pathways that inhibit Cdc2 activity, activation of the protein kinases Chk1 and Chk2 by the protein kinases Atm and Atr. Chk1 and Chk2 inhibit Cdc2 by inactivating Cdc25, the phosphatase that normally activates Cdc2. Chk1, Chk2, Atm and Atr also contribute to the activation of p53 in response to genotoxic stress and therefore play multiple roles. p53 induces transcription of the reprimo, B99, and mcg10 genes, all of which contribute to the arrest of cells in G2, but the mechanisms of cell cycle arrest by these genes is not known. Repression of the
topoisomerase
II gene by p53 helps to block entry into mitosis and strengthens the G2 arrest. In summary, multiple overlapping p53-dependent and p53-independent pathways regulate the G2/M transition in response to genotoxic stress.
...
PMID:Regulation of the G2/M transition by p53. 1131 28
Mutations of the retinoblastoma tumor suppressor, pRb, or its cyclin-
cyclin-dependent kinase
(
CDK
) regulatory kinases or
CDK
inhibitors, allows unrestrained E2F activity, leading to unregulated cell cycle progression. However, overexpression of E2F-1 also sensitizes cells to apoptosis, suggesting that targeting this pathway may be of therapeutic benefit. Enforced expression of E2F-1 in interleukin-3-dependent myeloid cells led to preferential sensitivity to the
topoisomerase
II inhibitor, etoposide, which was independent of p53 accumulation. Pretreatment of the E2F-1-expressing cells with ICRF-193, a second
topoisomerase
II inhibitor that does not cause DNA damage, protected these cells against etoposide-induced apoptosis. However, ICRF-193 cooperated with other DNA-damaging agents to induce apoptosis. Enforced expression of E2F-1 led to accumulation of p53 protein. An E2F-1 mutant that is defective in inducing cell cycle progression also induced p53, suggesting that p53 was responding directly to E2F, and not to secondary events caused by inappropriate cell cycle progression (i.e., DNA damage). Thus,
topoisomerase
II inhibition and DNA damage cooperate to selectively induce apoptosis in cells that have mutations in the pRb pathway.
...
PMID:Topoisomerase IIalpha mediates E2F-1-induced chemosensitivity and is a target for p53-mediated transcriptional repression. 1132 40
To determine whether cell cycle regulation or alteration plays a role in oncogenesis and cytodifferentiation of odontogenic epithelium, cell cycle-related factors, including cyclin D1, p16INK4a, p21(WAF1/Cip1) and p27Kip1 proteins,
DNA topoisomerase
IIalpha and histone H3 mRNA, were examined in 8 tooth germs and 31 ameloblastomas. Cyclin D1 was expressed in epithelial cells near the basement membrane in tooth germs and ameloblastomas, suggesting that this protein participates in cell proliferation in odontogenic epithelium. Immunoreactivity for p16 protein was observed in most epithelial cells in tooth germs and ameloblastomas. Expression of p21 protein was detected in most epithelial cells in tooth germs and ameloblastomas, but not in keratinizing or granular cells in variants of ameloblastomas. Expression of p27 protein was chiefly found in central polyhedral cells and keratinizing cells in tooth germs and ameloblastomas. These
cyclin-dependent kinase
inhibitors were well preserved in ameloblastomas as compared with tooth germs, suggesting that the odontogenic epithelium is strictly regulated by these factors. The cell cycle phase/cellular proliferation markers,
DNA topoisomerase
IIalpha and histone H3 mRNA, were localized in scattered epithelial cells attached to the basement membrane in tooth germs and ameloblastomas.
...
PMID:Detection of cell cycle-related factors in ameloblastomas. 1133 68
DNA topoisomerase II
is required for mitotic chromosome condensation and segregation. Here we characterize the effects of inhibiting
DNA topoisomerase II
activity in plant cells using the non-DNA damaging
topoisomerase
II inhibitor ICRF-193. We report that ICRF-193 abrogated chromosome condensation in cultured alfalfa (Medicago sativa L.) and tobacco (Nicotiana tabaccum L.) mitoses and led to bridged chromosomes at anaphase. Moreover, ICRF-193 treatment delayed entry into mitosis, increasing the frequency of cells having a pre-prophase band of microtubules, a marker of late G2 and prophase, and delaying the activation of
cyclin-dependent kinase
. These data suggest the existence of a late G2 checkpoint in plant cells that is activated in the absence of
topoisomerase
II activity. To determine whether the checkpoint-induced delay was a result of reduced cyclindependent kinase activity, mitotic cyclin B2 was ectopically expressed. Cyclin B2 bypassed the ICRF-193-induced delay before mitosis, and correspondingly, reduced the frequency of interphase cells with a pre-prophase band. These data provide evidence that plant cells possess a
topoisomerase
II-dependent G2 cell cycle checkpoint that transiently inhibits mitotic CDK activation and entry into mitosis, and that is overridden by raising the level of CDK activity through the ectopic expression of a plant mitotic cyclin.
...
PMID:A topoisomerase II-dependent checkpoint in G2-phase plant cells can be bypassed by ectopic expression of mitotic cyclin B2. 1242 28
Some anticancer drugs, but not all, inhibit replication of human immunodeficiency virus (HIV) and thus, exhibit a therapeutic potential. Such drugs, unlike the traditional HIV enzyme inhibitors, could suppress HIV strains that are resistant to inhibitors of viral enzymes, decrease proviral burden in vivo, or reduce reservoirs of infection via killing infected cells. Thus, they may be an effective adjunct therapy or perhaps result in a cure. The incidence of HIV infection and AIDS mortalities continue to increase worldwide, including the United States and parts of Africa, with a parallel increase in a number of other manifestations, including AIDS defining malignancies. The basis for continual spread of HIV presumably in large part stems from the viral resistance to previously successful drugs and the lack of curative antiretroviral drugs. To reverse these trends, other approaches for AIDS therapy must be developed. One possibility is the development of potent anticancer drugs, that exhibit anti-HIV activities. At least four chemically and pharmacologically distinct classes of anticancer drugs, i.e. certain
cyclin-dependent kinase
inhibitors (CDKIs),
topoisomerase
1 enzyme (top 1) inhibitors, non-nucleoside antimetabolites, and estrogen receptor ligands are promising candidates. These drugs, at high doses are used for cancer therapy; at lower concentrations they exhibit anti-HIV activities in cultured cells. While the antiretroviral and the anticancer activities of the cdk inhibitor flavopiridol appear to be mutually exclusive and unrelated in cells and animal model(s) of HIV disease, the top 1 inhibitor 9-nitrocamptothecin, as well as the cdk-inhibitor roscovitine inhibit replication of HIV via selective sensitization of HIV-infected cells to apoptosis. In contrast, the inhibitory effects of these compounds are different from other cancer therapeutics that, at toxic concentrations, activate HIV either in cultured cells (such as certain ingenol and butyrate derivatives) and/or in patients (such as the widely used cyclophosmamide and cisplatin). This quality may lead to the eradication of proviral reservoirs, which is not accomplished by the currently available antiretroviral drugs. In this review, relevant available clinical and in vitro data that either support or discourage using certain anticancer drugs for treatment of HIV disease, and the rationales for developing novel antiretroviral drugs that may target infected cells rather than viral proteins are discussed.
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PMID:A novel approach to develop anti-HIV drugs: adapting non-nucleoside anticancer chemotherapeutics. 1467 May 89
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