Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.31.1 (micrococcal nuclease)
 2,818 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have compared the chromatin structure in the active and inactive states at loci encoding the major heat shock protein in Drosophila. DNAase I and micrococcal nuclease were used as probes of higher order organization and nucleosomal integrity. Such integrity is gauged here by the characteristic pattern of discrete DNA fragments produced at specific chromosomal loci by nucleolytic cleavage. The specific fragment patterns are visualized by gel electrophoresis, Southern blotting onto nitrocellulose sheets, hybridization with 32P-labeled cloned DNA containing the heat shock genes and autoradiography. Using this criterion, a disruption in nucleosomal and possibly in higher order organization are observed as indicated by a relative loss or smearing of the characteristic discrete DNA fragment patterns from the heat shock loci in the active state. The fragment patterns are restored when cells are allowed to recover from heat shock and these loci return to the inactive state.
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PMID:The chromatin structure of specific genes: II. Disruption of chromatin structure during gene activity. 45 50

Production of bacteriophages T2, T4, and T6 at 42.8 to 44 degrees C was increased from 8- to 260-fold by adapting the Escherichia coli host (grown at 30 degrees C) to growth at the high temperature for 8 min before infection; this increase was abolished if the host htpR (rpoH) gene was inactive. Others have shown that the htpR protein increases or activates the synthesis of at least 17 E. coli heat shock proteins upon raising the growth temperature above a certain level. At 43.8 to 44 degrees C in T4-infected, unadapted cells, the rates of RNA, DNA, and protein synthesis were about 100, 70, and 70%, respectively, of those in T4-infected, adapted cells. Production of the major processed capsid protein, gp23, was reduced significantly more than that of most other T4 proteins in unadapted cells relative to adapted cells. Only 4.6% of the T4 DNA made in unadapted cells was resistant to micrococcal nuclease, versus 50% in adapted cells. Thus, defective maturation of T4 heads appears to explain the failure of phage production in unadapted cells. Overproduction of the heat shock protein GroEL from plasmids restored T4 production in unadapted cells to about 50% of that seen in adapted cells. T4-infected, adapted E. coli B at around 44 degrees C exhibited a partial tryptophan deficiency; this correlated with reduced uptake of uracil that is probably caused by partial induction of stringency. Production of bacteriophage T7 at 44 degrees C was increased two- to fourfold by adapting the host to 44 degrees C before infection; evidence against involvement of the htpR (rpoH) gene is presented. This work and recent work with bacteriophage lambda (C. Waghorne and C.R. Fuerst, Virology 141:51-64, 1985) appear to represent the first demonstrations for any virus that expression of the heat shock regulon of a host is necessary for virus production at high temperature.
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PMID:Induction of the heat shock regulon of Escherichia coli markedly increases production of bacterial viruses at high temperatures. 244 14

Oviduct cells from estradiol-treated chicks were grown in primary culture. After 3-5 days of culture in medium containing estradiol, 90% of the cellular progesterone binding sites were detected in the cytosol. After exposure to [3H]progesterone at 37 degrees C, 80% of the progesterone binding sites were found in nuclear fractions. Progesterone receptor phosphorylation was assessed after incubating the cells with [32P]orthophosphate. Receptor components were immunoprecipitated with a specific polyclonal antibody (IgG-G3) and analyzed by NaDodSO4/PAGE and autoradiography. In the cytosol, constant amounts of 32P-labeled 110-kDa subunit (the B subunit, one of the progesterone-binding components of the receptor) and of the non-steroid-binding heat shock protein hsp90 were found, whether cells had been exposed to progesterone or not. No 32P-labeled 79-kDa subunit (the A subunit, another progesterone-binding subunit) was detected. Various procedures were used to solubilize nuclear progesterone receptor (0.5 M KCl, micrococcal nuclease, NaDodSO4), and in no case was 32P-labeled B subunit detected in the extracts. However, nonradioactive B subunit was detected by immunoblot in a nuclear KCl extract of progesterone-treated cells. These results suggest that the fraction of the B subunit that becomes strongly attached to nuclear structures is not phosphorylated upon exposure of cells to progesterone.
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PMID:Tightly bound nuclear progesterone receptor is not phosphorylated in primary chick oviduct cultures. 346 87