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Query: KEGG:D03345 (beta-Galactosidase)
 434 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The GATA motif (WGATAR) is found in the promoter regions of numerous Caenorhabditis elegans genes, including two intestine-specific genes, vit-2 and ges-1, in which it has been shown to be required for promoter function. The protein ELT-1, encoded by a single-copy gene homologous to the GATA family of vertebrate transcription factors, is potentially capable of interacting with this element. In order to determine whether ELT-1 is a transcriptional activator that recognizes this sequence, we have expressed it under the control of the GAL1 promoter in yeast. lacZ driven by the CYC1 promoter lacking an upstream activation sequence (UAS) but containing GATA sequences was used as a reporter. beta-Galactosidase was expressed upon induction only when GATA sequences were present, and expression was increased dramatically by additional binding sites. Deletion analysis demonstrated that the C terminus, containing only one of the two zinc fingers, is sufficient for activation. In addition, the DNA-binding domain and two transactivation regions were identified by fusing these isolated domains to previously defined domains of heterologous transcription factors. While most single base alterations in the GATA core sequence eliminated activity, an A to C change in position four, creating a GATC core, was found to increase activity significantly. The deleted ELT-1 protein containing only the C-terminal Zn finger was sufficient for activation in response to GATA, but both fingers were required for activation at GATC. A variety of sites with non-optimal sequences surrounding the GATA core also were found to be excluded better by the protein containing both Zn fingers. Furthermore, a fusion protein containing the entire ELT-1 DNA binding domain fused to the VP16 activation domain was found to have an even greater preference for the GATC core, as well as the optimal flanking bases. We conclude that, although ELT-1 having only its C-terminal finger is capable of activation in response to the WGATAR site, the presence of the upstream finger supplies additional base specificity.
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PMID:Activity of a C. elegans GATA transcription factor, ELT-1, expressed in yeast. 747 42

Previous studies using in vitro procedures have not clearly established whether the estrogen receptor (ER) acts as a monomer or dimer in the cell. We have used the yeast two-hybrid system as an in vivo approach to investigate the dimerization of the estrogen receptor in the absence and presence of estrogen and anti-estrogens. This system is independent of ER binding to the estrogen response element. Two vectors, expressing GAL4 DNA binding domain-human ER and GAL4 transactivation domain-human ER, were constructed. Control experiments showed that each fusion protein had a high affinity binding site for estradiol-17 beta and could transactivate an ERE-LacZ reporter gene in yeast similar to the wild type ER. The two fusion proteins, GAL4 DB-hER and GAL 4 TA-hER, were expressed in the yeast strain, PCY2, which carries a GAL1 promoter-lacZ reporter. ER dimerization was measured via reconstitution of GAL4 through interaction of the fusion proteins, which transactivates LacZ through the GAL1 promoter. When both ER fusion proteins were expressed, beta-galactosidase activity was estradiol-17 beta-inducible. Furthermore, we showed that both tamoxifen and ICI 182,780 also induced beta-galactosidase activity, albeit lower than that induced by estradiol-17 beta. These results strongly argue that ER dimerization is ligand-dependent and the dimer can be induced by estradiol-17 beta, tamoxifen, or ICI 182,780. We also treated the yeast containing the two fusion proteins with estradiol-17 beta and tamoxifen or ICI 182,780 simultaneously to determine the effects on ER dimerization. beta-Galactosidase activity was lower when the yeast was treated with a higher ratio of tamoxifen or ICI 182,780 to estrogen than estradiol-17 beta alone. Taken together, we conclude that ER dimerization is ligand (estradiol-17 beta, tamoxifen, or ICI 182, 780)-dependent, and we suggest that estradiol-17 beta-induced dimers are destabilized when estradiol-17 beta is used with tamoxifen or ICI 182,780 simultaneously.
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PMID:Yeast two-hybrid system demonstrates that estrogen receptor dimerization is ligand-dependent in vivo. 755 88

The effects of residual catabolite repression and the importance of induction timing were determined for a temperature-sensitive (ts) GAL-regulated stable yeast expression system. The Saccharomyces cerevisiae strain employed carries a reg1 mutation inhibiting catabolite repression, and a ts mutation enabling induction of the regulated GAL promoters by a temperature shift to 35 degrees C. Despite the reg1 mutation and induction method, glucose depressed lacZ expression from a GAL1 promoter during batch culture. beta-Galactosidase specific activity was consistently lower at higher initial glucose concentrations in both SDC (semi-defined) and YPDa (complex) media; decreases of 18-36% were observed as glucose concentration was increased between 1, 3, 5, and 10 g l-1. However, the reductions in beta-galactosidase specific activity due to residual catabolite repression were more than balanced by substantial improvements in biomass yield at higher glucose levels. Therefore, productivity rose with increasing glucose concentration; in YPDa medium, increasing initial glucose from 1 to 10 g l-1 resulted in a 2.6-fold increase in beta-galactosidase volumetric activity. Due to the negative effects of shifting temperature to 35 degrees C, the trade-offs between optimum growth and a lengthy induction period were also evaluated. Delaying the time of induction reduced final specific activities but improved cell yield, and waiting 14 h into batch culture to induce lacZ expression provided modest 9-15% improvements in overall productivity.
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PMID:Catabolite repression and induction time effects for a temperature-sensitive GAL-regulated yeast expression system. 776 17