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Query: EC:2.5.1.61 (
porphobilinogen deaminase
)
637
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
GATA-1 is a cys-2/cys-2 zinc finger transcriptional activator that is required for erythrocyte development in chimeric mice and contributes to the expression of all erythroid genes studied to date, including the
erythropoietin receptor
, glycophorin B, and
porphobilinogen deaminase
genes. Transactivation by GATA-1 is mediated by either an amino-terminal acidic domain, R1, or an independent adjacent domain, R2, and may involve the coordinate action of cofactors (NF-E2, EKLF, and Sp1) which bind adjacent cis-elements. To directly assess mechanisms of transactivation, we have developed an efficient cell-free transcription system using recombinant human GATA-1 (rhGATA-1) expressed in SF9 cells. Levels of baculoviral expression of GATA-1 were > or = 200-fold higher than endogenous levels in erythroid K562 cells. Factors from each source were essentially equivalent in molecular weight and DNA binding properties, and highly similar in phosphotryptic peptide composition. Notably, DNA binding was inhibited following treatment with alkaline phosphatase. In both SF9 and K562 cells, GATA-1 occurred largely as heterogeneous multimers, thus complicating its isolation by standard procedures. However, significant purification of this factor (> or = 100-fold; > or = 75% purity) was accomplished via DNA affinity chromatography. In cell-free assays, this rhGATA-1 was shown to be remarkably active in transactivating model erythroid promoters. This work establishes an efficient in vitro system for direct analyses of mechanisms, cofactors, and functional domains of GATA-1 which regulate transcription at defined proximal promoters.
...
PMID:In vitro transcription of erythroid promoters using baculoviral-expressed human GATA-1: purification, physicochemistry, and activities. 785 29
Human erythroleukemic K 562 cells were induced to were induced to differentiate along the erythroid lineage by anthracycline antitumor drugs, such as aclacinomycin (ACLA) and doxorubicin (DOX). Subsequent stimulation of heme and globin synthesis led to a differential quantitative expression of hemoglobins. Gower 1 (epsilon2, zeta2) was the major type for ACLA and X (epsilon2, gamma2) for DOX. Although ACLA and DOX increased both the expression of gamma-globin and
porphobilinogen deaminase
mRNAs, striking differences were observed in the expression of
erythropoietin receptor
mRNAs and in erythroid transcription factors GATA-1 and NF-E2, known to play a key role in erythroid gene regulation. Indeed, ACLA induces an increase either in the binding capacity of GATA-1 and NF-E2 or in the accumulation of
erythropoietin receptor
, GATA-1 and NF-E2 transcripts. In contrast, their expression with DOX was not significantly modified compared to uninduced cells, except for a slight decrease in NF-E2 expression on day 3. In conclusion, these data show that: 1. increased expression of erythroid transcription factors and erythroid genes are associated only with ACLA treatment, and 2. although cytotoxicity of both ACLA and DOX is certainly dependent on DNA intercalation, regulation of differentiation processes by these two drugs involves distinct mechanisms.
...
PMID:Evidence for distinct regulation processes in the aclacinomycin- and doxorubicin-mediated differentiation of human erythroleukemic cells. 860 80
Anthracycline antitumor drugs such as aclacinomycin (ACM) and doxorubicin (DOX) used in subtoxic concentrations induce erythroid differentiation of the erythroleukemic cell line K562. To elucidate the possible role of erythroid genes of the
erythropoietin receptor
(EpoR) and the transcription factor GATA-1 in this effect, the regulatory regions of the above genes and human epsilon- and gamma-globin and
porphobilinogen deaminase
(
PBGD
) genes were fused to the firefly luciferase gene. The resulting reporter constructs were tested in a transfection assay of the erythroleukemic cell line K562 stimulated to differentiate by treatment with the anthracycline drugs ACM and DOX or hemin (HEM). The results showed activation of the tested promoters after cell treatment with ACM, but not with DOX or HEM. In contrast to the mouse EpoR gene promoter, the activity of the human EpoR gene promoter (-659/-60) in the reporter construct was not modified by addition of the first intron sequence. In ACM-treated K562 cells, EpoR gene promoter activity completely correlated with EpoR and GATA-1 mRNA levels and the degree of erythroid maturation. In addition, ACM strongly activated the erythroid gene promoters that contain GATA binding sites. Nevertheless, less activation was also observed for the GATA-1 gene promoter (-312/-31) lacking any known GATA binding sites. Insertion of the GATA-1 gene enhancer with two canonic GATA binding sites, stimulated the ACM activation effect for EpoR and GATA-1 promoter-containing constructs. Mutation of the enhancer GATA binding sites abolished this effect. All the regulatory regions tested (except gamma-globin promoter) were completely inactive in nonerythroid COS7 cells. These data indicate that (1) two structurally different anthracycline analogues, DOX and ACM, differ in their differentiation mechanisms, and (2) ACM switches on the erythroid program of K562 cells, at least in part because of interaction with a factor(s) that recognizes the GATA binding sites in the promoter region of erythroid genes leading to their activation.
...
PMID:Activation of erythroid-specific promoters during anthracycline-induced differentiation of K562 cells. 863 8
Aclacinomycin (ACLA) and doxorubicin (DOX) were used at subtoxic concentrations to induce erythroid differentiation in the human leukemic cell line K562. Cell hemoglobinization was accompanied by the increased expression of genes encoding gamma-globin and
porphobilinogen deaminase
(
PBGD
), an enzyme of heme synthesis. By using run-on assays, ACLA was shown to induce an enhancement of the transcription of erythroid genes, including gamma-globin,
PBGD
,
erythropoietin receptor
, and GATA-1 transcription factor. In contrast, in DOX-treated cells, the transcription rate of these genes was unchanged in comparison with control cells. In addition, inhibition of mRNA synthesis with actinomycin D indicated that DOX induced an increased stability of
PBGD
and GATA-1 mRNAs, whereas ACLA did not affect the half-lives of these mRNAs. Because the increase in erythroid mRNA steady-state level in anthracycline-treated cells was inhibited by cycloheximide, this suggests that transcriptional activation in ACLA-treated cells and mRNA stabilization in DOX-treated cells were dependent on de novo protein synthesis. Finally, GATA-1 protein level was shown to be increased in ACLA-treated but not in DOX-treated cells. These two anthracyclines, although closely related in their structures, appeared to act as differentiation inducers by distinct mechanisms. Indeed, erythroid gene expression was demonstrated to be regulated transcriptionally by ACLA and mainly posttranscriptionally by DOX.
...
PMID:Transcriptional and posttranscriptional regulation of erythroid gene expression in anthracycline-induced differentiation of human erythroleukemic cells. 885 98
Butyric acid (BA) was shown to induce hemoglobinization of K562 cells in a dose- and time-dependent manner. The maximal differentiation (54% of hemoglobinized cells) was obtained with the 0.5 mM concentration, which induced a 60% inhibition of cell growth at day 3 without cytotoxicity. Parallel to the kinetics of hemoglobinization, a rapid increase in gamma-globin and
porphobilinogen deaminase
(
PBGD
) mRNAs was observed in BA-treated cells. This increase was time-dependent and higher for gamma-globin than for
PBGD
(six- and two-fold at day 3, respectively). In contrast,
erythropoietin receptor
mRNAs were not affected by BA treatment. Analysis of erythroid transcription factor mRNA levels during the time course of BA treatment showed, for the first time, an early and marked (up to three-fold) increase in p45 NF-E2 mRNA, contrasting with that of GATA-1 mRNA (<1.5-fold). Taken together, these results showed the rapid differentiating effect of BA and suggest the involvement of the NF-E2 transcription factor.
...
PMID:Time-course of butyric acid-induced differentiation in human K562 leukemic cell line: rapid increase in gamma-globin, porphobilinogen deaminase and NF-E2 mRNA levels. 930 15
Tumor cells, and particularly leukemic cells, can be considered as maturation-arrested cells which have escaped some normal control and continue to proliferate. This maturation arrest can be reversed by differentiation agents such as antitumor drugs currently used in conventional cytotoxic chemotherapy. In this respect, anthracyclines have been shown to trigger the differentiation of leukemic and solid tumor cells, but the molecular mechanisms by which such drugs lead to the differentiating phenotype are still poorly understood. Using human leukemic multipotent K562 cells, we have demonstrated that subtoxic concentrations of aclacinomycin (ACLA) and doxorubicin (DOX) preferentially stimulate the hemoglobinic pathway (globins and heme synthesis) and the expression of mRNAs of globins and of
porphobilinogen deaminase
(
PBGD
). However, our results indicate that both drugs exert this differentiating effect along distinct regulatory pathways. Indeed, only ACLA and not DOX induces the expression of
erythropoietin receptor
(EpoR) mRNAs and of membrane EpoR, as well as an overexpression of the erythroid transcription factors GATA-1 and NF-E2 known to play a central role in erythroid gene regulation. Similarly, using transfection assays, ACLA but not DOX activates the regulatory regions (promoters and enhancers) of GATA-1, EpoR,
PBGD
, epsilon- and gamma-globin genes. Finally, results of run-on assays indicate that ACLA induces an enhancement of the transcription rate of these erythroid genes whereas DOX preferentially increases stability of GATA-1, NF-E2 and
PBGD
mRNAs. In conclusion, ACLA mainly acts at the transcriptional level via specific activation of erythroid regulatory regions whereas DOX rather acts at the posttranscriptional level by increasing the half-lives of erythroid mRNAs.
...
PMID:Anthracyclines as tumor cell differentiating agents: effects on the regulation of erythroid gene expression. 938 64
