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)

These assessment of the consequences of irradiation on chromatin is complicated by endogenous nucleases. Isolation and prolonged storage of rat liver nuclei in buffers containing divalent metal ions activates these enzymes and promotes the degradation of chromatin. Irradiation of rat liver nuclei to dose levels of 20,000 rad under conditions in which endogenous nucleases are inhibited and analysis of the irradiated chromatin by sucrose density gradient centrifugation gave no evidence for monosomes or oligosomes. When chromatin from irradiated nuclei was digested with micrococcal nuclease, the levels of monosomes and oligosomes were identical to those of micrococcal nuclease, the levels of monosomes and oligosomes are identical to suggest that irradiation results in neither a direct fragmentation of linkers nor the sensitization of linkers for subsequent cleavage by micrococcal nuclease. Histones isolated from monosomes of irradiated and unirradiated nuclei were intact, showing no fragmentation or loss of residues, as judged by sodium dodecyl sulfate-polyacrylamide electrophoresis.
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PMID:Effect of irradiation and endogenous nucleases on rat liver chromatin. 608

A ribonucleoprotein (RNP) particle sedimenting at 10 S in sucrose gradients had been isolated from the post-polysomal fraction of homogenates of 14-day-old chick embryonic leg and breast muscle by sucrose gradient fractionation and gel filtration. The 10 S RNP contains a 4 S RNA species (base composition: AMP, .3%; GMP, 22.2%; CMP, 24.2%; and UMP, 23.2%), and shows three major bands in the 70-90-nucleotide size range by polyacrylamide gel electrophoresis in 99% formamide. The 4 S RNA does not contain oligo(U)- and oligo(A)-rich tracts. The RNP has a characteristic buoyant density of 1.410 g/ml, which corresponds to an RNA/protein ratio of about 1:4. The UV absorption spectra of the RNP is very distinct from that of its RNA component. Both 4 S RNA and the 10 S RNP are potent inhibitors of translation of a variety of mRNAs such as chick muscle poly(A)+ mRNA, rabbit globin mRNA, EMC virus RNA, and poly(A)- and mRNA of rat liver in micrococcal nuclease-treated rabbit reticulocyte lysate. The inhibitory action of the RNA and the RNP on mRNA translation appears to involve the initiation process. The RNA and RNP do not have a nuclease activity associated with them. The hyperchromicity profile of the inhibitory RNA with increasing temperature indicates that it does not contain a significant amount of double-stranded structure. This is also supported by the complete loss of biological activity of the RNA by treatment with pancreatic RNase. In contrast, the inhibitory activity of the RNP was resistant to RNase. Electrophoresis of the protein moieties of the inhibitory RNP using both one- and two-dimensional gel techniques in the presence of sodium dodecyl sulfate shows a complex pattern of polypeptides of Mr = 12,000-150,000. The protein pattern of the 10 S particle is quite different from those of free and polysomal mRNP and poly(A)-protein complexes of chick embryonic muscles, indicating that most, if not all of the mRNA-associated proteins, are absent in the 19 S RNP. The properties of the inhibitory RNA indicate that it is different from the various low molecular weight RNA species which are involved in the modulation of protein synthesis in cell-free systems. It is concluded that the 10 S particle represents a novel class of RNP, which may be involved in posttranscriptional regulation of protein synthesis in embryonic muscles.
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PMID:A ribonuclease-resistant cytoplasmic 10 S ribonucleoprotein of chick embryonic muscle. A potent inhibitor of cell-free protein synthesis. 611 23

Changes in the volume of rat liver nuclei have been monitored as a function of modifications in ionic environment (from 0 to 20 mM), temperature (from 4 to 37 degrees C), and pH (from 1 to 8). An abrupt reduction of nuclear volume occurred with increasing ion concentration, this contraction being more pronounced with bivalent (either Ca2+ or Mg2+) than with monovalent (either Na+ or K+) cations. The lowering of pH produced a similar effect. Parallel changes in chromatin structure took place at the same time as phase-like transitions. Atomic absorption spectroscopy allowed determination of free and nuclei-bound ions, pointing to the presence of a sizeable number of free binding sites for chromatin-DNA even within intact nuclei. DNA-phosphate sites appear to be neutralized by ions strictly according to the size of the electric charge and polyelectrolyte theory. Partial digestion (by micrococcal nuclease) or simple breaks (by chemical carcinogens) of the chromatin-DNA fiber caused respectively elimination or reduction of the abrupt volume changes in the intact nuclei. The apparent role of chromatin structure versus nuclear matrix in determining the shape and volume of intact nuclei is briefly discussed.
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PMID:Phase transitions in nuclei and chromatin. Is nuclear volume controlled by the chromatin or by the nuclear matrix? 621 Jan 46

The effects of inhibiting histone deacetylation on the maturation of newly replicated chromatin have been examined. HeLa cells were labeled with [3H]thymidine in the presence or absence of sodium butyrate; control experiments demonstrated that butyrate did not significantly inhibit DNA replication for at least 70 min. Like normal nascent chromatin, chromatin labeled for brief periods (0.5-1 min) in the presence of butyrate was more sensitive to digestion with DNase I and micrococcal nuclease than control bulk chromatin. However, chromatin replicated in butyrate did not mature as in normal replication, but instead retained approximately 50% of its heightened sensitivity to DNase I. Incubation of mature chromatin in butyrate for 1 h did not induce DNase I sensitivity: therefore, the presence of sodium butyrate was required during replication to preserve the increased digestibility of nascent chromatin DNA. In contrast, sodium butyrate did not inhibit or retard the maturation of newly replicated chromatin when assayed by micrococcal nuclease digestion, as determined by the following criteria: 1) digestion to acid solubility, 2) rate of conversion to mononucleosomes, 3) repeat length, and 4) presence of non-nucleosomal DNA. Consistent with the properties of chromatin replicated in butyrate, micrococcal nuclease also did not preferentially attack the internucleosomal linkers of chromatin regions acetylated in vivo. The observation of a novel chromatin replication intermediate, which is highly sensitive to DNase I but possesses normal resistance to micrococcal nuclease, suggests that nucleosome assembly and histone deacetylation are not obligatorily coordinated. Thus, while deacetylation is required for chromatin maturation, histone acetylation apparently affects chromatin organization at a level distinct from that of core particle or linker, possibly by altering higher order structure.
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PMID:Histone deacetylation is required for the maturation of newly replicated chromatin. 622 60

1. It has been reported that DNase I can be highly purified from pancreas extract by affinity chromatography on a dDNA-Sepharose column under non-digestive conditions. In the present study, the adsorption-elution of other nucleases on the column under non-digestive conditions was studied. 2. All the seven kinds of nucleases tested were adsorbed when applied on a dDNA-Sepharose column under conditions which did not allow the enzymes to hydrolyze the DNA. The non-digestive conditions were as follows. i) For DNase II (pI=10.2), pH 3.0 in the presence of 50 mM sodium sulfate (inhibitor), ii) for micrococcal nuclease (pI=9.6), pH 4.0 in the absence of Ca2+ (activator), iii) for restriction endonucleases Eco RI (pI=5+1), Hind III (pI=5+1), and Bam HI (pI=5+1), pH 4.0 in the presence of 20% glycerol and 0.1% Neopeptone (stabilizers), and iv) for nucleases S1 (pI=5+1) and nuclease P1 (pI=4.5), pH 7.0. At the respective pH's, the enzymes other than nucleases S1 and P1 were cationic so as to exhibit electrostatic attraction to the anionic dDNA-Sepharose. Although S1 and P1 were anionic, they still adsorbed to the column. 3. All the adsorbed nucleases described above were eluted by a concentration gradient of KCl without changing pH. The ionic strengths required for elution were 0.19 for DNase II, 0.53 for micrococcal nuclease, 0.73 for Eco RI, 0.72 for Hind III, 0.37 for Bam HI, 0.17 for P1, and 0.13 for S1. The fact that the ionic strength required for the elution of DNase I (pI=5.0) was 0.39 at pH 4.0 indicates that the former five enzymes except DNase II can be chromatographed with almost the same or higher efficiency than DNase I, because the proteins adsorbed with no-specific affinity could be mostly eluted at lower ionic strength. On the other hand, the fact that nucleases P1 and S1 were adsorbed in spite of electrostatic repulsion suggests that these two enzymes can also be effectively chromatographed, especially when other cationic proteins are previously removed by an appropriate method such as adsorption to a typical cation exchanger.
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PMID:Affinities of various nucleases to DNA-Sepharose under non-digestive conditions: survey for productive affinity chromatography. 628 26

A type I topoisomerase has been purified from avian erythrocyte nuclei. The most pure fraction contains one major polypeptide of Mr = 105,000 (80% of total) and several minor ones of lower molecular weight. Active forms of the topoisomerase were identified by covalently binding the enzyme to 32P-DNA, digesting with nuclease and detecting 32P labeled peptides by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Topoisomerase activity, as measured by the ability to covalently bind DNA, is associated with the following peptides: Mr = 105, 83, 54 and 30,000. The similar chromatographic properties of the various forms of topoisomerase suggests a common structural identity as previously proposed for the HeLa topoisomerase I (Liu, L.F. and Miller, K.G. (1981) Proc. Natl. Acad. Sci. USA 78, 3487-3491). The avian enzyme is similar to other eucaryotic type I DNA topoisomerases in that it covalently binds double and single stranded DNA forming an enzyme linked to the 3'-phosphoryl end and after binding to single stranded DNA it can transfer the single stranded donor DNA to an acceptor DNA possessing 5'-OH end groups. The binding site size of topoisomerase on DNA has also been determined using micrococcal nuclease to digest unprotected DNA in the native enzyme/DNA complex. The enzyme blocks access to the helix over a span of 25 bp. These findings are discussed in light of the distribution and function of topoisomerase I in chromatin.
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PMID:Biochemical characterization of topoisomerase I purified from avian erythrocytes. 630 57

The gene A protein cleaves phi X174 single-stranded DNA (ssDNA). The cleavage appears to be stoichiometric, whereby a gene A protein molecule breaks a phosphodiester bond and binds to the 5' end. The enzyme introduces mostly a single break in a circular ssDNA molecule. However, at high enzyme-to-DNA ratios, more than one break in the DNA could be observed. The cleavage of the ssDNA by gene A protein renders the DNA sensitive to the action of terminal transferase to incorporate [alpha -32P]ATP. Thus, the 3'OH end is free. All attempts to label the 5' end by T4-induced polynucleotide kinase and [gamma-32P]ATP failed. The formation of a gene A-ssDNA complex was demonstrated directly by using 3H-labeled gene A protein and 32P-labeled ssDNA in the reaction. Such a complex is resistant to treatments with 0.2 M NaOH, banding in CsCl, and boiling in 2.5% sodium dodecyl sulfate. Only treatment with a nuclease released the bound protein. Also, after cleaving [32P]ssDNA by gene A protein, followed by either DNase I or micrococcal nuclease digestion, a fraction of the 32P label remained resistant to nuclease treatment and comigrated with gene A protein on polyacrylamide gels.
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PMID:Cleavage of phi X174 single-stranded DNA by gene A protein and formation of a tight protein-DNA complex. 644 6

The phosphorylation of the high mobility group (HMG) proteins has been investigated in mouse Ehrlich ascites, L1210 and P388 leukemia cells, human colon carcinoma cells (HT-29), and Chinese hamster ovary cells. HMG 14 and 17, but not HMB 1 and 2, were phosphorylated in the nuclei of all cell lines with a serine being the site of modification for both proteins in Ehrlich ascites cells. Phosphorylation of HMG 14 and 17 was greatly reduced in cultured cells at plateau phase in comparison to log phase cells, suggesting that modification of HMG 14 and 17 is growth-associated. However, phosphorylation was not linked to DNA synthesis, since incorporation of 32P did not vary through G1 and S phase in synchronized Chinese hamster ovary cells. Treatment of HT-29 or Ehrlich ascites cells with sodium butyrate reduced HMG phosphorylation by 30 and 70%, respectively. The distribution of the phosphorylated HMG proteins in chromatin was examined using micrococcal nuclease and DNase I. 32P-HMG 14 and 17 were preferentially associated with micrococcal nuclease-sensitive regions as demonstrated by the release of a substantial fraction of the phosphorylated forms of these proteins under conditions which solubilized less than 3% of the DNA. Short digestions with DNase I did not show a marked release of 32P-HMG 14 or 17.
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PMID:The phosphorylation of high mobility group proteins 14 and 17 and their distribution in chromatin. 646 58

The molecular properties of the scrapie agent were investigated by subjecting partially purified preparations to electrophoresis on agarose gels. When electrophoresis was performed at room temperature in the presence of sodium dodecyl sulfate (NaDodSO4), most of the recoverable agent was found at the top of the gel, consistent with previous studies indicating aggregation of the agent upon exposure to elevated temperatures. In addition, less than 5% of the agent applied to the gel was found after electrophoresis, even though the study was performed with a low concentration of NaDodSO4 (0.1%). Further studies on the inactivation of the agent by NaDodSO4 suggest that this may be, in part, a function of the NaDodSO4: protein ratio in the sample. In contrast, sodium N-lauroyl sarcosinate (Sarkosyl) did not inactivate the agent in concentrations as high as 5% (wt/vol). Virtually all of the infectivity could be recovered after electrophoresis of the agent into 0.6% agarose gels at 4 degrees C in the presence of 0.2% Sarkosyl. Digestion of the preparations with micrococcal nuclease and proteinase K prior to Sarkosyl electrophoresis caused a substantial portion of the agent to migrate ahead of DNA fragments of 1 x 10(6) daltons. The behavior of the scrapie agent in electrophoretic gels is consistent with earlier studies showing that the monomeric form of the agent has a sedimentation coefficient of less than or equal to 40 S. Thus, the smallest or monomeric form of the agent is smaller than any known animal virus.
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PMID:Electrophoretic properties of the scrapie agent in agarose gels. 677 64

Cell cycle variations in the phosphorylation of chromatin-associated nonhistones were determined. Cells were radiolabeled with [32P]orthophosphate and chromatin was obtained by mild digestion of nuclei with micrococcal nuclease. The experiments were performed in the presence of a substrate inhibitor of alkaline phosphatase, beta-glycerophosphate. The results show that, while similar molecular weight species of phosphorylated nonhistones are associated with interphase chromatin through the HeLa cell cycle, the incorporation (32P cpm/micrograms of protein) profiles of selected major phosphononhistones show substantial changes. The most prominent peaks of specific radioactivity occur in the DNA synthesis phase (S phase). The phosphorylation states of the proteins of isolated metaphase chromosomes were also determined. Nonhistone proteins of isolated metaphase chromosomes are strikingly dephosphorylated, especially in comparison to histone H1. The phosphorylation of the major phosphononhistone of chromatin, which has a molecular weight of 55,000, was further characterized by techniques that included one-dimensional peptide mapping in sodium dodecyl sulfate-polyacrylamide gels and nonequilibrium pH gradient slab gel electrophoresis. Phosphoproteins are also components of the nuclear scaffold, and cell cycle variations in these proteins were investigated. The primary phosphorylated species has a molecular weight of 119,000. As with chromatin-associated nonhistones, this nuclear scaffold protein shows substantial incorporation of 32P in S phase, and a high level of incorporation also occurs close to mitosis.
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PMID:Phosphorylation of nonhistone proteins during the HeLa cell cycle. Relationship to DNA synthesis and mitotic chromosome condensation. 682 62


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