Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
Enzyme
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Target Concepts:
Gene/Protein
Disease
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Enzyme
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Query: EC:2.7.7.7 (
DNA polymerase
)
17,007
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The products of the tumor suppressor genes are considered to function as specific inhibitors of tumor cell growth. In this communication, we present evidence to show that these proteins inhibit tumor cell proliferation by participating in the activation of tumor cell differentiation. The
ML-1
human myeloblastic leukemia cells used in this study proliferate when treated with insulin-like growth factor I and transferrin but differentiate to monocytes when exposed to tumor necrosis factor alpha or transforming growth factor beta1, or to macrophage-like cells when treated with both these cytokines. Initiation of proliferation but not of differentiation was followed by a 20- to 25-fold increase in the nuclear level of the
DNA polymerase
-associated processivity factor PCNA and of the proliferation-specific transcription factor E2F1. In contrast, induction of differentiation but not of proliferation was followed by a 25- to 30-fold increase in the nuclear level of the tumor suppressor proteins p53 (wild type), pRb, and p130/Rb2 and of the p53-dependent cyclin kinase inhibitor p21/Cip1. p53 and p21/Cip1, respectively, inhibit the expression and activation of PCNA, whereas p130 and pRb, respectively, inhibit the expression and activation of E2F1. As a result, G1-S-associated DNA and mRNA synthesis is inhibited, growth uncoupled from differentiation, and maturation enabled to proceed. Where this function of the tumor suppressor proteins is impaired, the capacity for differentiation is lost, which leads to the sustained proliferation that is characteristic of the cancer cell.
...
PMID:Tumor suppressor proteins as regulators of cell differentiation. 976 53
The pharmacokinetics and pharmacodynamics of the novel clinical candidate 2'-C-cyano-2'-deoxy-1-beta-D-arabino-pentofuranosylcytosine (CNDAC) were investigated in human lymphoblastoid CCRF-CEM cells and human myeloblastic leukemia
ML-1
cells. Formation of CNDAC 5'-mono-, di-, and triphosphate (CNDACTP) was concentration-dependent; nucleotide accumulation was greater in the lymphoid cells than in the myeloid cells. The nucleotides were eliminated with linear kinetics from both lines, but were retained more effectively by the
ML-1
cells. DNA synthesis was selectively inhibited by a 4-hr treatment with CNDAC in CCRF-CEM and
ML-1
cells; the IC(50) values were 1 and 0.8 microM, respectively. Evaluation of the polymerization reaction of a primer on an M13mp19(+) template by human
DNA polymerase alpha
indicated that CNDACTP was incorporated effectively (K(m) = 0.22 microM) opposite a complementary dGMP in the template strand. CNDACTP competed with the normal substrate, dCTP, for incorporation, and the two nucleotides showed similar substrate efficiencies (V(max)/K(m): dCTP = 0.91; CNDACTP = 0.77). Primer extension was potently inhibited by CNDAC triphosphate (K(i) = 23 nM); once the analog had been incorporated, further extension was not observed in vitro, suggesting that primers containing a 3'-terminal nucleotide analog were high K(m) substrates for polymerase alpha. Thus, the ability of human leukemia cells to effectively accumulate and retain CNDACTP, coupled with the favorable kinetics of competition for incorporation into DNA, and the relatively strong ability of the analog to terminate further extension, are likely to contribute to the cytotoxic action of CNDAC.
...
PMID:Cellular pharmacokinetics and pharmacodynamics of the deoxycytidine analog 2'-C-cyano-2'-deoxy-1-beta-D-arabino-pentofuranosylcytosine (CNDAC). 1137 79
(E)-2'-deoxy-2'-(fluoromethylene)cytidine (FMdC) is a new analog of deoxycytidine with promising anticancer activity. We investigated the action of FMdC on DNA metabolism by evaluating its incorporation into DNA, its excision from DNA in vitro, and the role of the incorporation of FMdC into DNA in causing cytotoxicity. In vitro DNA primer extension demonstrated that FMdC nucleotides were incorporated with relatively high substrate efficiency into the C sites of the elongating DNA strand. Once incorporated, FMdC became a poor substrate for further chain elongation by DNA polymerases, resulting in a termination of DNA synthesis at the sites of incorporation. Furthermore, the 3' --> 5' exonuclease activity of
DNA polymerase
epsilon or wild-type p53 protein was ineffective in removing the incorporated FMdC from DNA in vitro. FMdC also showed potent cytotoxic activity against human leukemia and solid tumor cells. Incubation with a low concentration of FMdC (10 nM) induced cell cycle arrest at S or G1 phases, but the cells eventually died as the time of incubation increased. Compared with HL-60 cells, human myeloid
ML-1
cells with wild-type p53 were more sensitive to FMdC, but the S or G1 phase arrest did not seem to depend on the presence or absence of p53. Inhibiting the incorporation of FMdC into cellular DNA by aphidicolin suppressed the cytotoxic effect of the compound. We conclude that the incorporated FMdC nucleotide profoundly disrupts DNA synthesis and resists excision by exonucleases, and that incorporation of this analog into DNA is a key molecular event responsible for the drug's cytotoxicity.
...
PMID:Action of (E)-2'-deoxy-2'-(fluoromethylene)cytidine on DNA metabolism: incorporation, excision, and cellular response. 1175 24
